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TW200402812A - Substrate, wiring board, substrate for semiconductor package, semiconductor device, semiconductor package and its manufacturing method - Google Patents

Substrate, wiring board, substrate for semiconductor package, semiconductor device, semiconductor package and its manufacturing method Download PDF

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Publication number
TW200402812A
TW200402812A TW092106854A TW92106854A TW200402812A TW 200402812 A TW200402812 A TW 200402812A TW 092106854 A TW092106854 A TW 092106854A TW 92106854 A TW92106854 A TW 92106854A TW 200402812 A TW200402812 A TW 200402812A
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TW
Taiwan
Prior art keywords
layer
metal
metal layer
insulating resin
wiring board
Prior art date
Application number
TW092106854A
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Chinese (zh)
Other versions
TWI228785B (en
Inventor
Toshimasa Nagoshi
Osamu Shimada
Mitsuo Kikuchi
Kazuhisa Suzuki
Original Assignee
Hitachi Chemical Co Ltd
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Publication date
Priority claimed from JP2002153578A external-priority patent/JP2003347477A/en
Priority claimed from JP2002219544A external-priority patent/JP4196606B2/en
Priority claimed from JP2002231310A external-priority patent/JP4288912B2/en
Application filed by Hitachi Chemical Co Ltd filed Critical Hitachi Chemical Co Ltd
Publication of TW200402812A publication Critical patent/TW200402812A/en
Application granted granted Critical
Publication of TWI228785B publication Critical patent/TWI228785B/en

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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K3/00Apparatus or processes for manufacturing printed circuits
    • H05K3/40Forming printed elements for providing electric connections to or between printed circuits
    • H05K3/42Plated through-holes or plated via connections
    • H05K3/423Plated through-holes or plated via connections characterised by electroplating method
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/04Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer
    • H01L21/48Manufacture or treatment of parts, e.g. containers, prior to assembly of the devices, using processes not provided for in a single one of the groups H01L21/18 - H01L21/326 or H10D48/04 - H10D48/07
    • H01L21/4814Conductive parts
    • H01L21/4846Leads on or in insulating or insulated substrates, e.g. metallisation
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L21/00Processes or apparatus adapted for the manufacture or treatment of semiconductor or solid state devices or of parts thereof
    • H01L21/02Manufacture or treatment of semiconductor devices or of parts thereof
    • H01L21/04Manufacture or treatment of semiconductor devices or of parts thereof the devices having potential barriers, e.g. a PN junction, depletion layer or carrier concentration layer
    • H01L21/48Manufacture or treatment of parts, e.g. containers, prior to assembly of the devices, using processes not provided for in a single one of the groups H01L21/18 - H01L21/326 or H10D48/04 - H10D48/07
    • H01L21/4814Conductive parts
    • H01L21/4846Leads on or in insulating or insulated substrates, e.g. metallisation
    • H01L21/486Via connections through the substrate with or without pins
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L2224/10Bump connectors; Manufacturing methods related thereto
    • H01L2224/15Structure, shape, material or disposition of the bump connectors after the connecting process
    • H01L2224/16Structure, shape, material or disposition of the bump connectors after the connecting process of an individual bump connector
    • H01L2224/161Disposition
    • H01L2224/16151Disposition the bump connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive
    • H01L2224/16221Disposition the bump connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked
    • H01L2224/16225Disposition the bump connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked the item being non-metallic, e.g. insulating substrate with or without metallisation
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L2224/26Layer connectors, e.g. plate connectors, solder or adhesive layers; Manufacturing methods related thereto
    • H01L2224/31Structure, shape, material or disposition of the layer connectors after the connecting process
    • H01L2224/32Structure, shape, material or disposition of the layer connectors after the connecting process of an individual layer connector
    • H01L2224/321Disposition
    • H01L2224/32151Disposition the layer connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive
    • H01L2224/32221Disposition the layer connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked
    • H01L2224/32225Disposition the layer connector connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked the item being non-metallic, e.g. insulating substrate with or without metallisation
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L2224/42Wire connectors; Manufacturing methods related thereto
    • H01L2224/47Structure, shape, material or disposition of the wire connectors after the connecting process
    • H01L2224/48Structure, shape, material or disposition of the wire connectors after the connecting process of an individual wire connector
    • H01L2224/4805Shape
    • H01L2224/4809Loop shape
    • H01L2224/48091Arched
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L2224/42Wire connectors; Manufacturing methods related thereto
    • H01L2224/47Structure, shape, material or disposition of the wire connectors after the connecting process
    • H01L2224/48Structure, shape, material or disposition of the wire connectors after the connecting process of an individual wire connector
    • H01L2224/481Disposition
    • H01L2224/48151Connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive
    • H01L2224/48221Connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked
    • H01L2224/48225Connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked the item being non-metallic, e.g. insulating substrate with or without metallisation
    • H01L2224/48227Connecting between a semiconductor or solid-state body and an item not being a semiconductor or solid-state body, e.g. chip-to-substrate, chip-to-passive the body and the item being stacked the item being non-metallic, e.g. insulating substrate with or without metallisation connecting the wire to a bond pad of the item
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/01Means for bonding being attached to, or being formed on, the surface to be connected, e.g. chip-to-package, die-attach, "first-level" interconnects; Manufacturing methods related thereto
    • H01L2224/42Wire connectors; Manufacturing methods related thereto
    • H01L2224/47Structure, shape, material or disposition of the wire connectors after the connecting process
    • H01L2224/49Structure, shape, material or disposition of the wire connectors after the connecting process of a plurality of wire connectors
    • H01L2224/491Disposition
    • H01L2224/4912Layout
    • H01L2224/49171Fan-out arrangements
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/73Means for bonding being of different types provided for in two or more of groups H01L2224/10, H01L2224/18, H01L2224/26, H01L2224/34, H01L2224/42, H01L2224/50, H01L2224/63, H01L2224/71
    • H01L2224/732Location after the connecting process
    • H01L2224/73251Location after the connecting process on different surfaces
    • H01L2224/73265Layer and wire connectors
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01LSEMICONDUCTOR DEVICES NOT COVERED BY CLASS H10
    • H01L2224/00Indexing scheme for arrangements for connecting or disconnecting semiconductor or solid-state bodies and methods related thereto as covered by H01L24/00
    • H01L2224/91Methods for connecting semiconductor or solid state bodies including different methods provided for in two or more of groups H01L2224/80 - H01L2224/90
    • H01L2224/92Specific sequence of method steps
    • H01L2224/922Connecting different surfaces of the semiconductor or solid-state body with connectors of different types
    • H01L2224/9222Sequential connecting processes
    • H01L2224/92242Sequential connecting processes the first connecting process involving a layer connector
    • H01L2224/92247Sequential connecting processes the first connecting process involving a layer connector the second connecting process involving a wire connector
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K2201/00Indexing scheme relating to printed circuits covered by H05K1/00
    • H05K2201/03Conductive materials
    • H05K2201/0332Structure of the conductor
    • H05K2201/0335Layered conductors or foils
    • H05K2201/0355Metal foils
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K2203/00Indexing scheme relating to apparatus or processes for manufacturing printed circuits covered by H05K3/00
    • H05K2203/07Treatments involving liquids, e.g. plating, rinsing
    • H05K2203/0703Plating
    • H05K2203/0733Method for plating stud vias, i.e. massive vias formed by plating the bottom of a hole without plating on the walls
    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05KPRINTED CIRCUITS; CASINGS OR CONSTRUCTIONAL DETAILS OF ELECTRIC APPARATUS; MANUFACTURE OF ASSEMBLAGES OF ELECTRICAL COMPONENTS
    • H05K3/00Apparatus or processes for manufacturing printed circuits
    • H05K3/46Manufacturing multilayer circuits
    • H05K3/4644Manufacturing multilayer circuits by building the multilayer layer by layer, i.e. build-up multilayer circuits
    • H05K3/4647Manufacturing multilayer circuits by building the multilayer layer by layer, i.e. build-up multilayer circuits by applying an insulating layer around previously made via studs

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  • Engineering & Computer Science (AREA)
  • Manufacturing & Machinery (AREA)
  • Microelectronics & Electronic Packaging (AREA)
  • Ceramic Engineering (AREA)
  • Physics & Mathematics (AREA)
  • Condensed Matter Physics & Semiconductors (AREA)
  • General Physics & Mathematics (AREA)
  • Computer Hardware Design (AREA)
  • Power Engineering (AREA)
  • Production Of Multi-Layered Print Wiring Board (AREA)

Abstract

The present invention provides a manufacturing method of wiring board that contains the followings: the printing process conducted onto the insulation member having plural conductive bumps on its surface, in which the insulation resin having varnish flow-shape before being hardened is coated on the conductive bumps to have a thickness that submerges the conductive bumps through a printing process; the hardened process for hardening the insulation resin; and the grinding process for grinding the insulation resin to expose the conductive bumps.

Description

200402812 ⑴ , 玖、發明說明 · 【發明所屬之技術領域】 本發明是關於:半導體裝置所用的基板、配線板、半 導體封裝用基板、半導體裝置、半導體封裝及其製造方法 〇 【先前技術】 隨著對電子機器的小型化或高性能化需求的殷切’半 導體的積體度也在年年提高,輸入輸出端子也在增加。連 Φ 帶的,搭載半導體的半導體封裝體也需要很多的輸入輸出 端子,同時,也被要求小型化,因此局密度化一直在進展 。又,隨著近年來之電子零件的高密度化,配線板已被要 求提昇其高密度化。而對搭載於配線板的半導體封裝’同 樣的要求也在高漲。一般在半導體封裝,有將輸入輸出端 子成一列配置在封裝周邊的形態,及不僅周邊而是成多列 配置到內部的形態。前者是以QFP (Quad Flat Package)較 具代表性。 φ 爲了回應這種要求的半導體封裝,傳統的僅能在周邊 配置端子的引線框型的 SOP(Small Outline Package)或取 代QFP將其多端子化時,將需要縮小端子間距,但在0.5 mm以下間距的領域,與配線板的連接需要高度的技術。 後者的陣列型可以用較大的間距排列端子,因此較適合多 插梢化。傳統上,陣列型是具有連接梢的PGA(Pin Grid Array)較爲一般性,但與配線板的連接成爲插入型,不適 用於表面安裝。因此,以開發出可以作表面安裝的所謂的 -6 - (2) (2)200402812 BGA(Ball Grid Array)封裝。 另一方面,隨著電子機器的小型化,對封裝尺寸的進 一步小型化的要求更爲強烈。爲因應這種小型化,有一提 案建議使用尺寸與半導體晶片差不多同大的所謂晶片尺寸 的封裝(CSP ·· Chip Size Package)。這是,不僅半導體晶 片的周邊部,在安裝領域內也有與外部配線基板的連接部 ,亦即具有外部連接端子的封裝。具體例子是,包括:在 半導體晶片的表面接合附設突塊的聚醯亞胺薄膜,藉由金 引線與晶片進行電氣連接後,罐燒環氧樹脂加以封裝者 (NIKKEI MATERIALS & TECHNOLOGY 9 4 · 4,Ν ο · 1 4 0,P 1 8 - 1 9 ),或在暫用基板上,於相當於半導體晶片及外部 配線基板的連接部位置形成金屬突塊,面朝下焊接半導體 晶片後,在暫用基板上轉換塑模(Smallest Flip - Chip -Like Package CSP ; The Second VLSI Packaging Workshop of Japan, p 46 - 50 ? 1 994)者等 ° 此等半導體封裝在形成搭載半導體晶片,稱作插入基 板(interposer)的配線板(半導體封裝體用基板)中的外部連 接端子時,使用貫穿孔、通孔。一般,貫穿孔、通孔是採 預先使用鑽頭或雷射在基材的成爲連接端子部位穿孔,在 孔內塡充焊錫或導電糊漿,配設外部連接端子的方法。但 是,這種方法對縮小孔徑有一定的限度,因此業界一直在 期盼有更小型而高密度,且成本低廉的半導體封裝體用的 配線板。 因此在檢討,預先藉由蝕刻配設外部連接端子,然後 -7 · (3) (3)200402812 埋入成爲基材的樹脂的方法。例如,在日本特開2002 -043 4 67號公報記載有’使用樹脂埋入半蝕刻金屬箔的一 面而形成的金屬突塊(金屬柱),將其利用作爲基板的層間 連接用配線的半導體封裝。依據這種方法時,可以很容易 將外部連接端子細徑化,連接可靠性也可以提高。 另一方面’近年來爲了進一步提高半導體封裝的積體 度’開發成功在一個封裝內封裝複數個晶片的MCP(Multi Chip Package),同時也在嘗試以一個封裝實現稱作 SIP (System in Package)的以往是在平板上實現的系統。 這種封裝的形成方法,是在連接晶片與配線板後,用 樹脂淹埋而在其上形成配線,再加以堆疊的方法。 在這種情勢下,近年來對具有凹凸的構件或中間體, 使用樹脂淹埋的製程在增加。但是,對無機、有機物質成 複雜組合的半導體封裝或配線板,樹脂與銅配線、半導體 曰曰片等不同材料間的接合性很重要,同時,被要求沒有翹 曲、波浪形狀的高平坦性。 然而’形成樹脂層的方法是壓製樹脂片來形成時,對 有上述的凹凸的構件,樹脂的追隨性會成爲問題。同時, 要淹埋樹脂時,會擔心加在晶片的壓力會使晶片烈開。 同時’區域陣列安裝型的B G A或C S P基板的最小外 形尺寸,是因外部連接端子數、端子間距及基板的最小配 線規則、及用以搭載的配線板的可形成配線規則而定。這 表不’端子數愈多配線間距愈小,可形成的配線的最小間 距決定最小外形尺寸。 (4) 200402812 傳統的藉由貫穿孔電鍍,或雷射通孔電鍍層間連接的 半導體封裝用基板,要將基板的連接用墊配置在層間連接 部的直上部很難,而是在基板表面的離層間連接部較遠的 電路端部形成連接用墊。這成爲阻礙基板縮小的一個主因 。目前的最小配線間距,一般是5 0 μιη左右,因此使 BGA或CSP的外部連接端子間距爲0.5 mm間距時,400 端子時的外形尺寸將成爲1 2 mm四方前後。200402812 ⑴, 玖, Description of the invention · [Technical field to which the invention belongs] The present invention relates to: a substrate for a semiconductor device, a wiring board, a substrate for a semiconductor package, a semiconductor device, a semiconductor package, and a manufacturing method thereof. [Prior Art] With The demand for miniaturization or high performance of electronic devices has increased the integration of semiconductors, and the number of input and output terminals has also increased. Even the semiconductor package equipped with a Φ band also requires a lot of input and output terminals. At the same time, it is also required to be miniaturized, so the local density has been progressing. In addition, in recent years, with the increase in the density of electronic components, it has been required to increase the density of wiring boards. The same demands are placed on semiconductor packages' mounted on wiring boards. Generally, in a semiconductor package, there are a form in which input and output terminals are arranged in a row around the package, and a form in which not only the periphery but a plurality of rows are arranged inside. The former is represented by QFP (Quad Flat Package). φ In order to respond to this type of semiconductor package, traditional lead frame SOPs (Small Outline Packages) that can only have terminals on the periphery or multi-terminals instead of QFP will need to reduce the terminal pitch, but it is less than 0.5 mm In the field of pitch, connection to wiring boards requires a high degree of technology. In the latter array type, terminals can be arranged with a large pitch, and therefore it is more suitable for multi-pinning. Traditionally, the array type is a PGA (Pin Grid Array) with a connection tip, but the connection to the wiring board is a plug-in type, which is not suitable for surface mounting. Therefore, the so-called -6-(2) (2) 200402812 BGA (Ball Grid Array) package that can be surface-mounted has been developed. On the other hand, with the miniaturization of electronic equipment, the demand for further miniaturization of the package size has become stronger. To cope with this miniaturization, there is a proposal to use a so-called chip size package (CSP ·· Chip Size Package), which is almost the same size as a semiconductor wafer. This is not only a peripheral portion of a semiconductor wafer, but also a connection portion with an external wiring board in a mounting field, that is, a package having external connection terminals. Specific examples include: a polyimide film with bumps attached to the surface of a semiconductor wafer, and electrically connected to the wafer with gold leads, and potted with epoxy resin for encapsulation (NIKKEI MATERIALS & TECHNOLOGY 9 4 · 4, N ο · 1 4 0, P 1 8-1 9), or on a temporary substrate, a metal bump is formed at a position corresponding to the connection portion of the semiconductor wafer and the external wiring substrate, and the semiconductor wafer is soldered face down. Mold conversion on the temporary substrate (Smallest Flip-Chip-Like Package CSP; The Second VLSI Packaging Workshop of Japan, p 46-50? 1 994), etc When an external connection terminal in a wiring board (substrate for a semiconductor package) of a substrate is used, a through hole or a through hole is used. Generally, through-holes and through-holes are prepared by using a drill or a laser in advance to make holes in the connection terminal portion of the base material, filling the holes with solder or conductive paste, and providing external connection terminals. However, this method has a certain limit on reducing the aperture, so the industry has been looking forward to a smaller, higher-density, and low-cost wiring board for semiconductor packages. Therefore, in the review, a method of arranging external connection terminals by etching in advance, and then embedding the resin that becomes the base material was performed. For example, Japanese Patent Application Laid-Open No. 2002-043 4 67 describes a semiconductor package in which a metal bump (metal pillar) formed by embedding one side of a half-etched metal foil with a resin is used as a wiring for interlayer connection of a substrate. . According to this method, the external connection terminal can be easily reduced in diameter, and the connection reliability can be improved. On the other hand, in order to further improve the integration degree of semiconductor packages in recent years, MCP (Multi Chip Package) for packaging multiple chips in one package has been successfully developed. At the same time, it is also trying to implement SIP (System in Package) in one package. The previous system was implemented on a tablet. This package is formed by connecting a wafer and a wiring board, and then submerging it with a resin to form wiring thereon, and then stacking the wiring. In this situation, in recent years, the number of processes for resin-buried components or intermediates with unevenness has increased. However, for semiconductor packages or wiring boards with a complex combination of inorganic and organic substances, the bonding between resin and different materials such as copper wiring and semiconductor wafers is very important. At the same time, it is required to have high flatness without warpage and wave shape . However, when the resin layer is formed by pressing a resin sheet, the followability of the resin becomes a problem for members having the above-mentioned unevenness. At the same time, when the resin is to be buried, there is a concern that the pressure applied to the wafer may cause the wafer to open strongly. At the same time, the minimum external dimensions of the BG A or C S P substrate of the 'area array mounting type' are determined by the number of external connection terminals, the terminal pitch, and the minimum wiring rule of the substrate, and the wiring rule that can be used for the mounted wiring board. This indicates that the more the number of terminals, the smaller the wiring pitch, and the minimum pitch of the wiring that can be formed determines the minimum external dimensions. (4) 200402812 Conventional semiconductor package substrates that are connected by interlayer plating by through-hole plating or laser through-hole plating. It is difficult to place the substrate connection pads directly above the interlayer connection, but on the surface of the substrate. A connection pad is formed at a circuit end portion farther from the interlayer connection portion. This has become a major cause of hindering substrate shrinkage. At present, the minimum wiring pitch is generally about 50 μm. Therefore, when the pitch of the external connection terminals of the BGA or CSP is 0.5 mm, the external dimensions at 400 terminals will be around 12 mm square.

第5圖表示使用傳統的貫穿孔電鍍連接方式半導體封 裝用基板的半導體封裝的截面圖。在形成有貫穿孔電鍍連 接部104的絕緣樹脂層106上搭載半導體晶片105,而以 封裝材1 08加以封裝。在絕緣樹脂層1 06的上面及下面設 有連接到貫穿孔電鍍連接部1 04的電路1 1 1。上面及下面 的電路1 1 1施加有Ni/ Αιι電鍍109。此基板的下面以露 出焊錫球用墊的狀態塗抹有抗焊錫劑1 1 2,焊錫球用墊上 設有焊錫突塊1 1 〇。在這種半導體封裝用基板,因爲無法 在貫穿孔電鍍連接部104的直上方設藉由金引線107與半 導體晶片1 05連接的線焊接用的連接用墊,因此是從貫穿 孔電鍍連接部1 04布放電路1 1 1,在其前端,亦即在絕緣 樹脂上的電路部分配置連接用墊1 02。另一方面,第6圖 所示的日本特開2002 - 043467號公報所記載的半導體封 裝的基板的層間連接用配線是金屬柱1 03。但是,藉由線 焊接與半導體晶片105的連接並不在金屬柱103直上方的 電路Π 1,而是用抗焊錫劑1 1 2被覆該部分,而在設於電 路1 1 1前端的絕緣樹脂上的連接用墊1 02連接。 -9- (5) 200402812 【發明內容】Fig. 5 is a cross-sectional view of a semiconductor package using a conventional through-hole plated connection semiconductor packaging substrate. A semiconductor wafer 105 is mounted on the insulating resin layer 106 on which the through-hole plated connection portion 104 is formed, and is sealed with a sealing material 108. Circuits 1 1 1 connected to the through-hole plated connection portions 104 are provided above and below the insulating resin layer 106. The upper and lower circuits 1 1 1 are applied with Ni / Aluminum plating 109. The lower surface of this substrate is coated with a solder resist 1 12 in a state where a pad for solder balls is exposed, and a solder bump 1 1 0 is provided on the pad for solder balls. In such a substrate for a semiconductor package, since a connection pad for wire bonding connected to the semiconductor wafer 105 through the gold lead 107 cannot be provided directly above the through-hole plated connection portion 104, the connection portion 1 is plated from the through-hole. 04 Lay out the circuit 1 1 1 and arrange the connection pad 102 on the front end, that is, the circuit part on the insulating resin. On the other hand, the wiring for interlayer connection of the semiconductor packaged substrate described in Japanese Patent Application Laid-Open No. 2002-043467 shown in Fig. 6 is a metal pillar 103. However, the connection to the semiconductor wafer 105 by wire bonding is not on the circuit Π 1 directly above the metal pillar 103, but the portion is covered with a solder resist 1 1 2 and the insulating resin provided on the front end of the circuit 1 1 1 The connection is made with pads 02. -9- (5) 200402812 [Summary of the invention]

本發明提案,能夠很容易在製造半導體封裝用基板或 其他配線板時使用的有凹凸的構件,形成樹脂層的方法。 而通常在配線構件,特別是在具有導電性突起的構件形成 樹脂層時,塗抹未硬化狀態的樹脂再使其硬化時,便會發 生樹脂的收縮,或起因於構件與樹脂之熱膨脹差,產生翹 曲或波浪。爲了抑制形成翹曲或波浪,有使用高比率混合 無機粒子的低收縮樹脂的方法,但這種方法存在有,樹脂 與構件的接合性會變差的問題。本發明是在樹脂層的形成 方法以外,進一步提供可以形成接合性良好,不會發生翹 曲或波浪的樹脂層的方法。The present invention proposes a method for easily forming a resin layer on a member having irregularities used in manufacturing a substrate for a semiconductor package or another wiring board. In general, when a wiring member, particularly a member having conductive protrusions, forms a resin layer, when an uncured resin is applied and cured, resin shrinkage occurs, or due to the difference in thermal expansion between the member and the resin. Warping or waves. In order to suppress the formation of warpage or waves, there is a method using a low shrinkage resin in which inorganic particles are mixed at a high ratio, but this method has a problem that the adhesion between the resin and the member is deteriorated. The present invention provides a method for forming a resin layer having good bonding properties without warping or wave formation in addition to the method for forming a resin layer.

亦即,本發明提案藉由印刷塗抹淸漆狀態的樹脂,再 使其硬化而形成樹脂層的方法,作爲在,1 .在具有導電性 突起的金屬箔形成樹脂層,然後藉由硏磨使導電性突起露 出的製程製造的半導體封裝用基板、配線板,2.在具有導 電性突起的導體與絕緣樹脂構成的配線配線構件形成樹脂 層,然後藉由硏磨使導電性突起露出的製程製造的半導體 封裝用基板、配線板,3 ·在配線板安裝晶片或被動零件後 以樹脂淹埋,而形成樹脂層,在其上面配設配線的內設元 件型的半導體封裝用基板、配線板,等3者形成樹脂層的 方法。 亦即,本發明係關於下列(1)〜(2 1)。 (1)包含:在表面有複數個導電性突起的絕緣構件, 藉由印刷塗抹硬化前的流動狀淸漆狀態的絕緣樹脂,塗抹 -10- (6) (6)200402812 到導電性突起被絕緣樹脂埋沒的厚度的印刷製程;令印刷 的絕緣樹脂硬化的硬化製程;以及,硏磨絕緣樹脂使導電 性突起的前端露出的硏磨製程的配線板的製造方法。 (2) 配線板爲半導體封裝用基板的(1)項所述之配線 板的製造方法。 (3) 配線構件爲表面具有複數個導電性突起的金屬箔 的(1)或(2)項所述之配線板的製造方法。 (4) 配線構件爲:絕緣樹脂層、絕緣樹脂層兩面之層 間相互連接的導體層、及絕緣樹脂層的至少一面上有導電 性突起者的(1)或(2)項所述之配線板的製造方法。 (5) 在硬化製程後進行硏磨製程的(1)〜(4)項中任一 項所述之配線板的製造方法。 (6) 包含:在表面有複數個導電性突起的絕緣構件, 藉由印刷塗抹硬化前的流動狀淸漆狀態的絕緣樹脂,塗抹 到導電性突起被絕緣樹脂埋沒的厚度的印刷製程;將印刷 之絕緣樹脂乾燥到失去流動性,但是在完全硬化以前之半 硬化狀態的乾燥製程;硏磨乾燥到半硬化狀態的絕緣樹脂 ’使導電性突起的前端露出的硏磨製程;硏磨後令絕緣樹 脂完全硬化的硬化製程的(1 )〜(4)項中任一項所述之配線 板的製造方法。 (7) 包含:在配線構件的具有導電性突起的面,印刷 呈流動狀的淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性 ’但是在完全硬化以前之半硬化狀態,再按順序分別印刷 ,成分與絕緣樹脂(1)不同,呈流動狀的淸漆狀態的絕緣 -11 - 200402812 (7) 樹脂(2),及成分與絕緣樹脂(2)不同,呈流動狀的淸漆狀 態的絕緣樹脂(3 )的至少兩種絕緣樹脂,乾燥到失去流動 性,但是在完全硬化以前之半硬化狀態,藉此將由絕緣樹 脂(1)層、絕緣樹脂(2)層及絕緣樹脂(3)層之至少3層所構 成的多層絕緣樹脂層,形成爲導電性突起被絕緣樹脂埋沒 的厚度的製程;令多層絕緣樹脂層中的所有絕緣樹脂同時 完全硬化的硬化製程;以及,硏磨多層絕緣樹脂層,使導 電性突起的前端露出的硏磨製程的(1)〜(4 )項中任一項所 述之配線板的製造方法。 (8) 在硏磨製程後進行硬化製程的(7)項所述之配線 板的製造方法。 (9) 在形成多層絕緣樹脂層的製程中,絕緣樹脂(i ) 使用與配線構件的接著性良好的絕緣樹脂,包含絕緣樹脂 (2 )層及絕緣樹脂(3 )層的第2層以上的各層則使用,具有 可以降低製作的配線板發生翹曲的特性的絕緣樹脂的(7) 項或(8)項所述之配線板的製造方法。 (1 〇)在形成多層絕緣樹脂層的製程中,藉由印刷以 任意位置、形狀、厚度,形成無機或有機粒子的含有率互 異的樹脂、或基本樹脂構造不相同的樹脂,然後,堆疊樹 脂,藉此形成,性質互異的樹脂混合存在於絕緣樹脂中的 任意處所的樹脂層的(7)項或(8)項所述之配線板的製造方 法。 (11)藉由(1)項〜(10)項中任一項所述的方法製造的 配線板。 (8) (8)200402812 (12) 藉由(1)項〜(10)項中任一項所述的方法製造的 半導體封裝。 (13) 使用(12)項所述之半導體封裝用基板的半導體 封裝。 (1 4)將電子零件安裝於配線板後以絕緣樹脂淹埋, 形成絕緣樹脂層,在絕緣樹脂層上設配線的內設元件型的 配線板的製造方法,係將電子零件安裝於配線板後,藉由 印刷塗抹硬化前的流動狀淸漆狀態的絕緣樹脂埋沒電子零 件,令印刷的絕緣樹脂硬化,形成絕緣樹脂層,爲其特徵 的製造方法。 (1 5 )電子零件是半導體晶片,內設元件型的配線板 是內設元件型的半導體封裝的(1 4)項所述之方法。 (16)包含:在配線構件的電子零件安裝面,印刷呈 流動狀淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性,但 是在完全硬化以前之半硬化狀態,再按順序分別印刷,成 分與絕緣樹脂(1)不同,呈流動狀的淸漆狀態的絕緣樹脂 (2),及成分與絕緣樹脂(2)不同,呈流動狀的淸漆狀態的 絕緣樹脂(3 )的至少兩種絕緣樹脂,乾燥到失去流動性, 但是在完全硬化以前之半硬化狀態,藉此將由絕緣樹脂 (1)層、絕緣樹脂(2)層及絕緣樹脂(3)層之至少3層所構成 的多層絕緣樹脂層,形成爲導電性突起被絕緣樹脂埋沒的 厚度的製程;令多層絕緣樹脂層中的所有絕緣樹脂同時完 全硬化的硬化製程;以及,在多層絕緣樹脂層上設配線的 製程的(14)項或(15)項所述之配線板的製造方法。 (9) (9)200402812 (1 7)在形成多層絕緣樹脂層的製程後,將多層絕緣 樹脂層的表面硏磨成平坦後進行硬化製程的(1 6)項所述之 方法。 (18)在形成多層絕緣樹脂層的製程中,絕緣樹脂(1 ) 使用與配線板及電子零件的接著性良好的絕緣樹脂,包含 絕緣樹脂(2)層及絕緣樹脂(3)層的第2層以上的各層則使 用,具有可以降低製作的內設元件型的配線板發生翹曲的 特性的絕緣樹脂的(16)項或(17)項所述之配線板的製造方 法。 (1 9)在形成多層絕緣樹脂層的製程中,藉由印刷以 任意位置、形狀、厚度,形成無機或有機粒子的含有率互 異的樹脂、或基本樹脂構造不相同的樹脂,然後,堆疊樹 脂,藉此形成,性質互異的樹脂混合存在於絕緣樹脂中的 任意處所的樹脂層的(1 6)〜(1 8)中任一項所述之方法。 (20) 藉由(14)〜(19)項中任一項所述之方法製造的 內設元件型配線板。 (21) 藉由(14)〜(19)項中任一項所述之方法製造的 內設元件型半導體封裝。 又,本發明提供包含:1 )將與配線材料的接合性良 好的樹脂,以硬化前的具流動性的淸漆狀態塗抹一薄層, 塗抹後,將其乾燥到不具流動性的未完全硬化的半硬化狀 態,使其成爲第1層的製程;2)在不具流動性的半硬化 狀態的第1層的樹脂層上面,以未硬化前的淸漆狀態的液 狀’塗抹混合成不會發生翹曲或波浪的樹脂,同樣將其乾 -14- (10) (10)200402812 燥到不具流動性的未完全硬化的半硬化狀態,使其成爲第 2層的製程;3 )爲了取得樹脂層的平衡,以流動狀淸漆 狀態在第2層上塗抹與第1層相同或不相同的樹脂,塗抹 後’將其乾燥到不具流動性的未完全硬化的半硬化狀態, 使其成爲第3層的製程;4)使半硬化狀態的所有樹脂整 批硬化成完全硬化的狀態的製程,的製造方法。 同時’本發明的目的是在提供,半導體封裝用基板等 的基板,不變更BGA或CSP的最小配線間距或端子數、 及配線板的配線規則,便能夠形成更小的半導體封裝的基 板、半導體封裝用基板,使用此基板的半導體裝置及半導 體封裝。 蝕刻金屬箔而形成的突塊用樹脂加以淹埋,使成層間 連接用的配線的基板,跟傳統的藉由貫穿孔電鍍進行層間 連接的C S P或B G A用的基板不相同,層間連接部完全被 金屬埋沒。本發明人發現,層間連接部由金屬完全埋沒時 ,可以在其層間連接部的直上方配設連接用墊,C S P或 B G A可以不改變最小配線間距,便能夠藉由簡單的配線 圖案的設計變更將其小型化,而依據此認知完成本發明。 亦即,本發明係關於,下列的(22)〜(3 2)項所述之基 板、半導體封裝用基板,半導體裝置及半導體封裝。 (22)具有:絕緣樹脂層;埋沒在絕緣樹脂層中,貫 穿到絕緣樹脂層兩面的層間連接用金屬柱;及在金屬柱的 直上方,形成於絕緣樹脂層的至少一面上的電路,金屬柱 與電路是藉由蝕刻金屬箔而形成,連接用墊設在金屬柱直 -15- (11) (11)200402812 上方的電路上的基板。 (23) 電路是在金屬柱的直上方,形成於絕緣樹脂層 的一面上的金屬層的(22)項所述之基板。 (24) 金屬柱由第1金屬構成,電路由蝕刻條件與第 1金屬不同的第2金屬構成,金屬箔具有第1金屬層及第 2金屬層,絕緣樹脂層、電路及金屬柱是藉由,選擇性蝕 刻金屬箔的第1金屬層,在第2金屬層上形成成爲金屬柱 的第1金屬的突塊,在第2金屬層的形成第1金屬突塊的 面上,形成第1金屬突塊露出前端面狀埋沒在絕緣樹脂中 的絕緣樹脂層,接著,選擇性蝕刻第2金屬層以形成電路 ,而形成的(23)項所述之基板。 (25) 金屬柱由第1金屬層及蝕刻條件與第1金屬層 不同的第2金屬層構成,電路由蝕刻條件與第2金屬層不 同的第3金屬層構成,金屬箔以第2金屬層爲中間層具有 第1金屬層、第2金屬層及第3金屬層,絕緣樹脂層、電 路及金屬柱是藉由,選擇性蝕刻金屬箔的第1金屬層,在 第2金屬層上形成第1金屬的突塊,接著,選擇性蝕刻金 屬箔的第2金屬層,形成成爲金屬柱的第〗金屬層及第2 金屬層構成的金屬的突塊,接著,在金屬箔的形成金屬突 塊的面上,形成由第1金屬層及第2金屬層構成的金屬突 塊露出前端面狀埋沒在絕緣樹脂中的絕緣樹脂層,接著, 選擇性蝕刻第3金屬層以形成電路,而形成的(23)項所述 之基板。 (26) 金屬柱由第1金屬構成,電路由蝕刻條件與第 (12) (12)200402812 1金屬層不同的第2金屬層及蝕刻條件與第2金屬層不同 的第3金屬層構成,金屬箔以第2金屬層爲中間層具有第 1金屬層、第2金屬層及第3金屬層,絕緣樹脂層、電路 及金屬柱是藉由,選擇性蝕刻金屬箔的第1金屬層,在第 2金屬層上形成成爲金屬柱的第1金屬的突塊,在第2金 屬層的形成第1金屬的突塊的面上,形成第1金屬的突塊 露出前端面狀埋沒在絕緣樹脂中的絕緣樹脂層,接著,分 別選擇性鈾刻第3金屬層及第2金屬層以形成電路,而形 成的(23)項所述之基板。 (2 7)具有:絕緣樹脂層;埋沒在絕緣樹脂層中,貫 穿到絕緣樹脂層兩面的層間連接用金屬柱;及在金屬柱的 直上方,形成於絕緣樹脂層的至少一面上的電路,金屬柱 是藉由蝕刻金屬箔而形成,連接用墊設在金屬柱直上方的 電路上的半導體封裝用基板。 (28) 具備有,(22)〜(26)項中任一項所述的基板及 搭載於基板的半導體晶片,在基板的金屬柱直上方,設於 電路上的連接用墊與半導體晶片的連接用墊,藉由線焊接 連接在一起的半導體裝置。 (29) 具備有,(22)〜(26)項中任一項所述的基板及 搭載於基板的半導體晶片,在基板的金屬柱直上方,設於 電路上的連接用墊與半導體晶片的連接用墊,藉由倒裝晶 片焊接方式連接在一起的半導體裝置。 (30) 具備有,(22)〜(26)項中任一項所述的基板及 搭載於基板的電子零件,電子零件的外部連接端子在基板 -17- (13) (13)200402812 的金屬柱直上方,與設於電路上的連接用墊,在該連接用 墊上連接在一起的半導體裝置。 (3 1)密封(2 8 )項所述的半導體裝置的半導體晶片搭 載面側而成的半導體裝置。 (3 2)密封(29)項所述的半導體裝置的半導體晶片搭 載面側而成的半導體裝置。 又,本發明的目的是在提供,在預先藉由蝕刻等在金 屬薄片設外部連接端子,然後以作爲基材的樹脂淹埋外部 連接端子的方法製造的半導體封裝用基板等配線板,提高 金屬與樹脂的密接性的方法。在這種配線板,金屬與樹脂 的密接性成爲可靠性的重要因素。密接性大部分依存於樹 脂的種類、密接的金屬的種類、金屬的接觸面的狀態,例 如表面形狀。而金屬的表面狀態在金屬是銅而樹脂是環氧 樹脂時,光澤面與粗化面的兩種狀態常是粗化面的密接性 較佳。樹脂是聚醯亞胺樹脂時,在密接後的初期狀態,光 澤面與粗化面的兩種狀態常是光澤面的密接性較佳,但吸 濕試驗後光澤面與粗化面的兩種狀態反轉,變成粗化面的 密接性較佳。本發明人等發現,以上述方法使用的多層化 的金屬箔,與樹脂的接觸面選擇跟樹脂的接合性良好的金 屬層非常重要,同時,與樹脂的接合面使用跟樹脂的接合 性良好的金屬表面狀態非常重要,而依據此項認知完成本 發明。 亦即,本發明係關於下列的(3 3 )〜(5 8 )項。 (3 3 )具備有:樹脂層;樹脂層的至少一面上的電路 -18- (14) (14)200402812 ;從電路至樹脂層的相反面突出在樹脂層中的複數個柱狀 的外部連接端子,電路及外部連接端子之接觸樹脂層的表 面經過粗化,爲其特徵的配線板。 (3 4 )電路與樹脂層接觸的層,使用與樹脂層的密接 性良好的金屬層的(3 3)項所述之配線板。 (3 5 )電路與樹脂層接觸的層,使用容易粗化的金屬 層的(3 3)項所述之配線板。 (36) 可當作半導體封裝體用基板使用的(33)〜(35) 項中之任一項所述的配線板。 (37) 具備有:(33)〜(35)項中任一項所記載的配線 板;搭載於配線板的半導體晶片;及用以封裝配線板的半 導體晶片搭載面的封裝材料的半導體封裝體。 (38) 對具有薄片部及從薄片部的一面突出的複數個 柱狀的外部連接端子的金屬薄片,將其具有外部連接端子 的表面粗化’在金屬薄片的經粗化的表面上,形成外部連 接端子露出前端狀埋沒在絕緣樹脂中的絕緣樹脂層,接著 ’去除一部分金屬薄片的薄片部直到樹脂層露出,藉此在 樹脂層上形成與外部連接端子連接的電路的(3 3 )項所述之 配線板的製造方法。 (39) 去除依序具有第1金屬層、第2金屬層及第3 金屬層的至少3層的多層金屬箔的第】金屬層的一部分, 直到露出第2層的金屬層,而在第2金屬層的露出面形成 複數個柱狀外部連接端子,藉此製成上述金屬薄片的(3 8) 項所述之配線板的製造方法。 -19- (15) 200402812 (40) 第2金屬層是與樹脂層的密接性很好的金屬層 的(3 9)項所述之配線板的製造方法。 (41) 第2金屬層是很容易粗化的金屬層的(39)項所 述之配線板的製造方法。That is, the present invention proposes a method of forming a resin layer by printing and painting a resin in a varnished state, and curing the resin layer as follows. 1. A resin layer is formed on a metal foil having conductive protrusions, and then is made by honing. A substrate for a semiconductor package and a wiring board manufactured by a process in which conductive protrusions are exposed; 2. A resin layer is formed on a wiring wiring member made of a conductor having a conductive protrusion and an insulating resin, and then the conductive protrusion is exposed by honing; Substrates and wiring boards for semiconductor packages, 3 · Submerged in resin on the wiring board to form a resin layer after mounting wafers or passive components to form a resin layer, and there are built-in component-type semiconductor packaging substrates, wiring boards, etc. Three methods for forming a resin layer. That is, the present invention relates to the following (1) to (2 1). (1) Including an insulating member having a plurality of conductive protrusions on its surface, and applying a flowing varnished insulating resin before hardening by printing, and applying -10- (6) (6) 200402812 to the conductive protrusions to be insulated A printing process of a resin-embedded thickness; a hardening process of hardening a printed insulating resin; and a method of manufacturing a wiring board by a honing process of honing an insulating resin to expose a tip of a conductive protrusion. (2) The method for manufacturing a wiring board according to (1), wherein the wiring board is a substrate for a semiconductor package. (3) The method of manufacturing a wiring board according to item (1) or (2), wherein the wiring member is a metal foil having a plurality of conductive protrusions on its surface. (4) The wiring member is an insulating resin layer, a conductor layer connected to each other on both sides of the insulating resin layer, and a wiring board according to item (1) or (2) in which at least one side of the insulating resin layer has conductive protrusions. Manufacturing method. (5) A method for manufacturing a wiring board as described in any one of (1) to (4) in which the honing process is performed after the hardening process. (6) Including an insulating member having a plurality of conductive protrusions on the surface, and a printing process of applying a flowing varnished insulating resin before hardening to a thickness where the conductive protrusions are buried by the insulating resin by printing; The insulating resin is dried to lose its fluidity, but it is a semi-hardened drying process before it is completely hardened; the honing drying of the insulating resin to a semi-hardened state is a honing process in which the front end of the conductive protrusion is exposed; The method for manufacturing a wiring board according to any one of (1) to (4) in a hardening process in which a resin is completely hardened. (7) Contains: printed on the surface of the wiring member with conductive protrusions, the insulating resin (1) in the state of flowing varnish is printed, dried to lose fluidity, but in a semi-hardened state before fully cured, and then in order Separately printed, the composition is different from the insulating resin (1), and it is in the state of flowing lacquer. 11-200402812 (7) Resin (2), and the composition is different from the insulating resin (2), it is in the state of flowing lacquer. At least two types of insulating resin (3) are dried to lose fluidity, but in a semi-hardened state before being completely hardened, whereby the insulating resin (1) layer, insulating resin (2) layer, and insulating resin (3 ) A multilayer insulating resin layer composed of at least 3 layers, forming a process in which the conductive protrusions are buried by the insulating resin; a hardening process in which all the insulating resins in the multilayer insulating resin layer are completely hardened at the same time; and honing the multiple layers The method of manufacturing a wiring board according to any one of (1) to (4) in a honing process in which an insulating resin layer and a tip of a conductive protrusion are exposed. (8) A method for manufacturing a wiring board according to item (7) in which a hardening process is performed after the honing process. (9) In the process of forming the multilayer insulating resin layer, the insulating resin (i) uses an insulating resin with good adhesion to the wiring member, and includes the second layer or more of the insulating resin (2) layer and the insulating resin (3) layer. For each layer, the method of manufacturing a wiring board according to item (7) or (8), which has the characteristics of reducing the warpage of the produced wiring board, is used. (10) In the process of forming a multi-layer insulating resin layer, a resin having different contents of inorganic or organic particles or a resin having a different basic resin structure is formed at any position, shape, and thickness by printing, and then stacked The resin is formed by the method of manufacturing a wiring board according to item (7) or (8) of a resin layer in which resins having mutually different properties are mixed in any place in an insulating resin. (11) A wiring board manufactured by the method according to any one of the items (1) to (10). (8) (8) 200402812 (12) A semiconductor package manufactured by the method described in any one of the items (1) to (10). (13) A semiconductor package using the semiconductor package substrate described in (12). (1 4) A method for manufacturing an internal component type wiring board in which an electronic component is mounted on a wiring board and flooded with an insulating resin to form an insulating resin layer, and wiring is provided on the insulating resin layer, after the electronic component is mounted on the wiring board The manufacturing method is characterized by burying electronic parts by printing and applying a flowing varnished insulating resin before hardening to harden the printed insulating resin to form an insulating resin layer. (1 5) The electronic component is a semiconductor wafer, and the wiring board having a built-in type is a method described in (14) of the semiconductor package having a built-in type. (16) Including: printing the insulating resin (1) in the state of flowing varnish on the mounting surface of the electronic components of the wiring member, and drying until it loses fluidity, but in the semi-hardened state before it is completely hardened, and then printed separately in order, At least two kinds of insulating resins (2) having a composition different from the insulating resin (1) and flowing in a varnished state, and at least two kinds of insulating resins (3) having a composition different from the insulating resin (2) and in a flowing varnished state Insulating resin is dried until it loses fluidity, but it is in a semi-hardened state before it is completely hardened. Thereby, a multilayer composed of at least 3 layers of insulating resin (1) layer, insulating resin (2) layer, and insulating resin (3) layer Insulating resin layer is formed by a process in which conductive protrusions are buried by the insulating resin; a hardening process in which all insulating resins in the multilayer insulating resin layer are completely hardened at the same time; and a process of providing wiring on the multilayer insulating resin layer (14 ) Or (15) The method for manufacturing a wiring board. (9) (9) 200402812 (1 7) After the process of forming the multilayer insulating resin layer, honing the surface of the multilayer insulating resin layer to be flat and then performing the hardening process described in (16). (18) In the process of forming the multilayer insulating resin layer, the insulating resin (1) uses an insulating resin with good adhesion to wiring boards and electronic parts, and includes a second layer of the insulating resin (2) layer and an insulating resin (3) layer. Each layer above the layer is used. The method for manufacturing a wiring board according to item (16) or (17), which has an insulating resin that can reduce the warpage of the built-in type wiring board. (19) In the process of forming a multilayer insulating resin layer, resins having different contents of inorganic or organic particles or resins having different basic resin structures are formed at any position, shape, and thickness by printing, and then stacked The resin is formed by the method according to any one of (16) to (18) in which resins having mutually different properties are mixed in a resin layer in any place in an insulating resin. (20) A component-type wiring board manufactured by the method described in any one of (14) to (19). (21) A built-in type semiconductor package manufactured by the method described in any one of (14) to (19). In addition, the present invention includes: 1) applying a thin layer of a resin having a good bonding property to a wiring material in a state of flowable varnish before curing, and after applying, drying it to incomplete curing without fluidity Semi-hardened state, making it the first layer of the process; 2) on the resin layer of the first layer of the non-flowable semi-hardened state, the liquid state of the lacquered state before hardening is mixed to prevent Warped or wavy resins are also dried -14- (10) (10) 200402812 and dried to a semi-hardened state with incomplete hardening without fluidity, making it the second layer process; 3) In order to obtain the resin For the balance of the layers, apply the same or different resin as the first layer to the second layer in the state of flowing lacquer, and after drying, 'dry it to a semi-hardened state with incomplete hardening without fluidity, making it the first A three-layer process; 4) A manufacturing process in which all the resins in a semi-hardened state are cured in a batch to a completely hardened state. At the same time, the purpose of the present invention is to provide substrates such as substrates for semiconductor packaging without changing the minimum wiring pitch or number of terminals of the BGA or CSP, and the wiring rules of the wiring board, so that the substrates and semiconductors of smaller semiconductor packages can be formed. A packaging substrate, a semiconductor device and a semiconductor package using the substrate. The bumps formed by etching the metal foil are buried with resin, so that the substrate for the wiring for interlayer connection is different from the conventional CSP or BGA substrate for interlayer connection by through-hole plating, and the interlayer connection part is completely metal. Buried. The inventors have discovered that when the interlayer connection portion is completely buried by metal, a connection pad can be provided directly above the interlayer connection portion, and CSP or BGA can change the simple wiring pattern design without changing the minimum wiring pitch. It has been miniaturized and completed the present invention based on this knowledge. That is, the present invention relates to the substrates, substrates for semiconductor packages, semiconductor devices, and semiconductor packages described in the following (22) to (32). (22) an insulating resin layer; a metal pillar for interlayer connection buried in the insulating resin layer and penetrating both sides of the insulating resin layer; and a circuit formed on at least one side of the insulating resin layer directly above the metal pillar, the metal The pillar and the circuit are formed by etching a metal foil, and the connection pad is provided on the circuit above the metal pillar straight -15- (11) (11) 200402812. (23) The circuit is the substrate described in (22) of the metal layer formed on one side of the insulating resin layer directly above the metal pillar. (24) The metal pillar is composed of the first metal, the circuit is composed of the second metal having different etching conditions from the first metal, the metal foil has the first metal layer and the second metal layer, and the insulating resin layer, the circuit, and the metal pillar are formed by The first metal layer of the metal foil is selectively etched to form bumps of the first metal serving as metal pillars on the second metal layer, and the first metal is formed on the surface of the second metal layer on which the first metal bumps are formed. The bump exposes the front end of the insulating resin layer buried in the insulating resin, and then the second metal layer is selectively etched to form a circuit, thereby forming the substrate according to item (23). (25) The metal pillar is composed of a first metal layer and a second metal layer having a different etching condition from the first metal layer, the circuit is composed of a third metal layer having a different etching condition from the second metal layer, and the metal foil is a second metal layer The intermediate layer includes a first metal layer, a second metal layer, and a third metal layer. The insulating resin layer, the circuit, and the metal pillar are formed by selectively etching the first metal layer of the metal foil to form a first metal layer on the second metal layer. 1 metal bump, and then the second metal layer of the metal foil is selectively etched to form a metal bump composed of the first metal layer and the second metal layer of the metal pillar, and then a metal bump is formed on the metal foil. A metal bump composed of a first metal layer and a second metal layer is formed on the surface, and an insulating resin layer buried in the insulating resin is exposed at the front end surface. Then, the third metal layer is selectively etched to form a circuit. (23) The substrate according to item (23). (26) The metal pillar is composed of the first metal, and the circuit is composed of the second metal layer having different etching conditions from (12) (12) 200402812 1 metal layer and the third metal layer having different etching conditions from the second metal layer. The foil has a first metal layer, a second metal layer, and a third metal layer with the second metal layer as an intermediate layer. The insulating resin layer, the circuit, and the metal pillar are formed by selectively etching the first metal layer of the metal foil. Bumps of the first metal forming the metal pillars are formed on the 2 metal layer, and the bumps forming the first metal are buried on the surface of the second metal layer where the bumps of the first metal are exposed and buried in the insulating resin. The insulating resin layer is then selectively etched with the third metal layer and the second metal layer to form a circuit, and the substrate according to item (23) is formed. (2 7) comprising: an insulating resin layer; a metal pillar for interlayer connection buried in the insulating resin layer and penetrating to both sides of the insulating resin layer; and a circuit formed on at least one side of the insulating resin layer directly above the metal pillar, The metal pillar is formed by etching a metal foil, and the connection pad is provided on a circuit board for a semiconductor package directly above the metal pillar. (28) The substrate according to any one of (22) to (26), and a semiconductor wafer mounted on the substrate. The connection pad provided on the circuit and the semiconductor wafer directly above the metal pillar of the substrate are provided. A connection pad is a semiconductor device connected together by wire bonding. (29) The substrate according to any one of (22) to (26), and a semiconductor wafer mounted on the substrate. The connection pad provided on the circuit and the semiconductor wafer directly above the metal pillar of the substrate are provided. A connection pad is a semiconductor device connected together by flip chip bonding. (30) The substrate according to any one of (22) to (26) and the electronic component mounted on the substrate, and the external connection terminals of the electronic component are on the substrate -17- (13) (13) 200402812 metal The semiconductor device is directly above the column and is connected to a connection pad provided on the circuit, and the connection pad is connected to the connection pad. (3 1) A semiconductor device in which the semiconductor wafer mounting surface side of the semiconductor device according to (2 8) is sealed. (3 2) A semiconductor device in which the semiconductor wafer mounting surface side of the semiconductor device according to the item (29) is sealed. Another object of the present invention is to provide a wiring board such as a substrate for semiconductor package manufactured by a method in which external connection terminals are provided on a metal sheet by etching or the like in advance, and then the external connection terminals are flooded with a resin as a base material, so that Method of resin adhesion. In such wiring boards, the adhesion between metal and resin becomes an important factor for reliability. Much of the adhesion depends on the type of resin, the type of metal that is in contact, and the state of the metal contact surface, such as the surface shape. On the other hand, when the surface state of the metal is copper and the resin is an epoxy resin, the two states of the glossy surface and the roughened surface are usually the roughened surfaces, and the adhesion is better. When the resin is a polyimide resin, in the initial state after the adhesion, the two states of the glossy surface and the roughened surface are often good adhesion of the glossy surface, but the two types of the glossy surface and the roughened surface are after the moisture absorption test. The state is reversed and the adhesion to the roughened surface is better. The present inventors have found that it is very important to select a metal layer having good adhesion with the resin at the contact surface with the resin for the multilayered metal foil used by the above-mentioned method. The state of the metal surface is very important, and the present invention has been completed based on this knowledge. That is, the present invention relates to the following items (3 3) to (5 8). (3 3) comprising: a resin layer; circuits on at least one side of the resin layer-18- (14) (14) 200402812; a plurality of columnar external connections protruding from the resin layer from the circuit to the opposite side of the resin layer Surfaces of terminals, circuits, and external connection terminals that are in contact with the resin layer are roughened, which is a characteristic wiring board. (3 4) As the layer in contact with the resin layer, the wiring board according to item (3) of the metal layer having good adhesion to the resin layer is used. (3 5) As the layer in contact with the resin layer, the wiring board according to item (3) of the metal layer which is easy to roughen is used. (36) The wiring board according to any one of (33) to (35), which can be used as a substrate for a semiconductor package. (37) A semiconductor package including: the wiring board according to any one of (33) to (35); a semiconductor wafer mounted on the wiring board; and a packaging material for packaging a semiconductor wafer mounting surface of the wiring board. . (38) A metal sheet having a sheet portion and a plurality of columnar external connection terminals protruding from one side of the sheet portion is formed by roughening the surface having the external connection terminals on the roughened surface of the metal sheet to form The external connection terminal exposes the insulating resin layer buried in the insulating resin at the front end, and then a portion of the metal foil is removed until the resin layer is exposed, thereby forming a (3 3) item of a circuit connected to the external connection terminal on the resin layer. The manufacturing method of the wiring board. (39) A part of the first metal layer of the multilayer metal foil having at least three layers of the first metal layer, the second metal layer, and the third metal layer in sequence is removed until the second metal layer is exposed, and A plurality of columnar external connection terminals are formed on the exposed surface of the metal layer, whereby the method for manufacturing a wiring board according to item (3) of the above-mentioned metal sheet is produced. -19- (15) 200402812 (40) The second metal layer is a method of manufacturing a wiring board according to the item (3) of (9), which is a metal layer with good adhesion to a resin layer. (41) The second metal layer is a method for manufacturing a wiring board according to item (39), which is a metal layer that can be easily roughened.

(4 2)第1金屬層、第2金屬層及第3金屬層是鄰接 層的蝕刻條件互異的層,第1金屬層之部分去除是藉由蝕 刻,電路之形成是藉由依序鈾刻第1金屬層及第2金屬層 ,而去除其一部分而形成的(39)〜(41)項中任一項所述之 配線板的製造方法。(4 2) The first metal layer, the second metal layer, and the third metal layer are layers with mutually different etching conditions. Part of the first metal layer is removed by etching, and the circuit is formed by sequential uranium etching. The manufacturing method of the wiring board as described in any one of (39)-(41) formed by removing a part of 1st metal layer and a 2nd metal layer.

(43) 將具有:金屬層的第1層(1);在第1層的一面 上的複數個金屬柱(2);及包含與樹脂層的密接性很好的 金屬層,形成在第1層的另一面上的一層以上的金屬層 (3)的複合金屬層之至少一層金屬層,從第1層依次去除 金屬柱下以外的部分,直到露出與樹脂層的密接性很好的 金屬層,藉此製作金屬薄片的(3 8)項所述之配線板的製造 方法。 (44) 將具有:金屬層的第1層(1);在第1層的一面 上的複數個金屬柱(2);及包含很容易粗化的金屬層,形 成在第1層的另一面上的一層以上的金屬層(3)的複合金 屬層之至少一層金屬層,從第1層依次去除金屬柱下以外 的部分,直到露出很容易粗化的金屬層,藉此製作金屬薄 片的(3 8)項所述之配線板的製造方法。 (45) 去除依序具有第1金屬層、第2金屬層及第3 金屬層的至少3層的多層金屬箔的第1金屬層的一部分, -20 - (16) (16)200402812 直到露出第2層的金屬層,而在第2金屬層的露出面形成 複數個金屬柱,接著,去除第2金屬層的金屬柱下部分以 外的一 分’直到露出第3金屬層,藉此製成上述金屬薄 片的(3 8)項所述之配線板的製造方法。 (46)第3金屬層是與樹脂層的密接性很好的金屬層 的(4 5)項所述之配線板的製造方法。 (4 7 )第3金屬層是很容易粗化的金屬層的(4 5 )項所 述之配線板的製造方法。 (48)第1金屬層、第2金屬層及第3金屬層是鄰接 層的蝕刻條件互異的層,第〗金屬層及第2金屬層的部分 去除是藉由蝕刻去除,電路之形成是藉由蝕刻去除第3金 屬層的一部分,而形成的(4 5 )〜(4 7 )項中任一項所述之配 線板的製造方法。 (4 9 )具備有:樹脂層;樹脂層的至少一面上的電路 ’從電路至樹脂層的相反面突出在樹脂層中的複數個柱狀 的外部連接端子’電路及外部連接端子之與樹脂層接觸的 層’是與樹脂層的密接性很好的金屬層,爲其特徵的配線 板。 (5 0)該配線板被用作半導體封裝用基板的(49)項所 述之配線板。 (51) 具^備有:(49)項所述的配線板;搭載於配線板 @ f # Μ晶片;及用以密封配線板的半導體晶片搭載面的 密封材料的半導體封裝體。 (52) 對具有薄片部及從薄片部的一面突出的複數個 -21 · (17) (17)200402812 柱狀的外部連接端子的金屬薄片,在其具有外部連接端子 的表面上,形成外部連接端子露出前端狀埋沒在絕緣樹脂 中的樹脂層,接著’去除一部分金屬薄片的薄片部直到樹 脂層露出,藉此在樹脂層上形成與外部連接端子連接的電 路的(49)項所述之配線板的製造方法,係薄片部的突出外 部端子的表面是與樹脂層的密接性很好的金屬表面的方法 〇 (5 3 )去除依序具有第1金屬層;與樹脂層的密接性 很好的第2金屬層;及第3金屬層的至少3層的多層金屬 箔的第1金屬層的一部分,直到露出第2層的金屬層,而 在第2金屬層的露出面形成複數個柱狀外部連接端子,藉 此製成上述金屬薄片的(5 1)項所述之配線板的製造方法。 (54) 第1金屬層、第2金屬層及第3金屬層是鄰接 層的蝕刻條件互異的層,第1金屬層之部分去除是藉由蝕 刻去除,電路之形成是藉由依序蝕刻第2金屬層及第2金 屬層,去除其一部分而形成的(5 2 )或(5 3 )項所述之配線板 的製造方法。 ^ (55) 將具有:金屬層的第1層(1);在第1層的一面 上的複數個金屬柱(2);及包含與樹脂層的密接性很好的 金屬層,形成在第1層的另一面上的一層以上的金屬層 (3 )的複合金屬層之至少一層金屬層,從第1層依次去除 金屬柱下以外的部分,直到露出與樹脂層的密接性很好的 金屬層,藉此製作金屬薄片的(5 2)項所述之配線板的製造 方法。 -22- (18) 200402812 (56) 去除依序具有第1金屬層、第2金屬層及與樹 脂層的密接性很好的第3金屬層的至少3層的多層金屬箔 的第1金屬層的一部分,直到露出第2層的金屬層,而在 第2金屬層的露出面形成複數個金屬柱,接著,去除第2 金屬層的金屬柱下部分以外的一部分,直到露出第3金屬 層,藉此製成上述金屬薄片的(5 2)項所述之配線板的製造 方法。(43) forming a first layer (1) having a metal layer; a plurality of metal pillars (2) on one side of the first layer; and a metal layer including a good adhesion to the resin layer, and forming the first layer At least one metal layer of the composite metal layer of one or more metal layers (3) on the other side of the layer, from the first layer, the portion other than the metal pillar is sequentially removed until the metal layer with good adhesion to the resin layer is exposed. In this way, a method for manufacturing a wiring board according to item (3) of (8) is used to produce a metal sheet. (44) A first layer (1) having a metal layer; a plurality of metal pillars (2) on one side of the first layer; and a metal layer containing easily roughened layers, formed on the other side of the first layer At least one metal layer of the composite metal layer of the above metal layer (3) is removed from the first layer in order from the lower part of the metal column in turn, until a metal layer that is easily roughened is exposed, thereby producing a metal sheet ( 3 The method for manufacturing a wiring board according to item 8). (45) Remove a part of the first metal layer of the multilayer metal foil having at least three layers of the first metal layer, the second metal layer, and the third metal layer in sequence, -20-(16) (16) 200402812 until the first The two metal layers are formed, and a plurality of metal pillars are formed on the exposed surface of the second metal layer. Next, a point other than the lower part of the metal pillars of the second metal layer is removed until the third metal layer is exposed, thereby preparing the above The manufacturing method of the wiring board as described in (3-8) of a metal sheet. (46) The third metal layer is a method for producing a wiring board according to item (4) to (5), which is a metal layer having excellent adhesion to a resin layer. (4 7) The third metal layer is a method for manufacturing a wiring board according to (4 5), which is a metal layer that can be easily roughened. (48) The first metal layer, the second metal layer, and the third metal layer are layers with mutually different etching conditions. Partial removal of the first metal layer and the second metal layer is performed by etching, and the circuit is formed. The method for manufacturing a wiring board according to any one of (4 5) to (4 7), which is formed by removing a part of the third metal layer by etching. (49) A resin layer; a circuit on at least one side of the resin layer, and a plurality of columnar external connection terminals protruding from the resin layer on the opposite side from the circuit to the resin layer; The layer 'layer-to-layer contact' is a metal layer with excellent adhesion to a resin layer, and is a wiring board characterized by this. (50) The wiring board is used as a wiring board described in (49) as a substrate for a semiconductor package. (51) A semiconductor package provided with: the wiring board described in the item (49); mounted on the wiring board @ f # Μchip; and a sealing material for sealing a semiconductor wafer mounting surface of the wiring board. (52) A metal sheet having a sheet portion and a plurality of -21 protruding from one side of the sheet portion. (17) (17) 200402812 A metal sheet having a columnar external connection terminal is provided with an external connection on a surface having the external connection terminal. The terminal exposes the resin layer buried in the insulating resin at the front end, and then a portion of the metal foil is removed until the resin layer is exposed, thereby forming the wiring described in (49) of the circuit connected to the external connection terminal on the resin layer. The manufacturing method of the plate is a method in which the surface of the protruding external terminal of the thin part is a metal surface with good adhesion to the resin layer. (5 3) Remove the first metal layer in order; good adhesion to the resin layer Part of the first metal layer of the multilayer metal foil of at least three layers of the third metal layer until the second metal layer is exposed, and a plurality of pillars are formed on the exposed surface of the second metal layer An external connection terminal, thereby producing the wiring board manufacturing method according to (5 1) of the above-mentioned metal sheet. (54) The first metal layer, the second metal layer, and the third metal layer are layers with mutually different etching conditions. Part of the first metal layer is removed by etching, and the circuit is formed by sequentially etching the first metal layer. The method for manufacturing a wiring board according to (5 2) or (5 3), in which the 2 metal layer and the second metal layer are formed by removing a part thereof. ^ (55) A first layer (1) having a metal layer; a plurality of metal pillars (2) on one side of the first layer; and a metal layer including a good adhesion to the resin layer are formed on the first layer At least one metal layer of the composite metal layer with more than one metal layer (3) on the other side of the first layer, and sequentially removes the part other than the metal pillar from the first layer until the metal with good adhesion to the resin layer is exposed. Layer, thereby producing a wiring board manufacturing method as described in (5 2) of a metal sheet. -22- (18) 200402812 (56) Remove the first metal layer of the multilayer metal foil having at least three layers of the first metal layer, the second metal layer, and the third metal layer with good adhesion to the resin layer in order. Part of the metal layer until the second metal layer is exposed, and a plurality of metal pillars are formed on the exposed surface of the second metal layer, and then a part other than the lower part of the metal pillar of the second metal layer is removed until the third metal layer is exposed, In this way, the method for manufacturing a wiring board according to item (5 2) of the above-mentioned metal sheet is produced.

(57) 第1金屬層、第2金屬層及第3金屬層是鄰接 層的蝕刻條件互異的層,第1金屬層及第2金屬層的部分 去除是藉由蝕刻去除,電路之形成是藉由蝕刻去除第3金 屬層的一部分,而形成的(5 6 )項所述之配線板的製造方法 (58)將半導體晶片搭載於(38)〜(52)項或(52)〜(57) 項中任一項所述之方法製造的配線板的具有電路的一面, 接著密封配線板的半導體晶片搭載面的配線板的製造方法 〇 以下’藉由上述(1)〜(10)的方法製造之配線板稱作 配線板A,半導體封裝用基板稱作半導體封裝用基板A, 上述(13)所述的半導體封裝稱作半導體封裝a,藉由上述 (14)〜(19)的方法製造之半導體裝置稱作半導體裝置B, 上述(22)〜(26)所述的基板稱作基板C,(27)所述的半導 體封裝用基板稱作半導體封裝用基板C,(28)、(29)及 (30) 所述的半導體裝置稱作半導體裝置Ci、c2及C3, (31) 及(32)所述之半導體封裝稱作半導體封裝ci及C2, -23- (19) (19)200402812 (33)〜(36)所述的配線板稱作配線板D,(37)所述的半導 體封裝稱作半導體封裝D,(49)〜(50)所述的半導體封裝 體稱作半導體封裝體E,(5 υ所述的半導體封裝稱作半導 體封裝Ε。 【實施方式】 〈配線板Α的製造方法,半導體封裝用基板A〉 本發明的配線板A的製造方法包含:在表面有複數 個導電性突起的絕緣構件,藉由印刷塗抹硬化前的流動狀 淸漆狀態的絕緣樹脂,塗抹到導電性突起被絕緣樹脂埋沒 的厚度的印刷製程;令印刷的絕緣樹脂硬化的硬化製程; 以及,硏磨絕緣樹脂使導電性突起的前端露出的硏磨製程 〇 以本發明的方法製造之配線板A有:例如,使用在 半導體封裝體的插入基板的半導體封裝用基板,半導體封 裝或搭載其他電子零件的母板等其他配線板。 本發明的配線板A的製造方法所使用的表面有複數 個導電性突起的配線構件,可以有如以下所列者。 1 .表面有導電性突起的金屬箔。例如有,藉由使用乾 薄膜抗蝕劑的蝕刻,使第1、第3金屬層的蝕刻條件與第 2金屬層不相同的金屬層的3層金屬箔的第1金屬層,成 爲柱狀突塊的金屬箔,及藉由使用乾薄膜抗蝕劑的蝕刻, 使上述3層金屬箔的第丨金屬層成爲柱狀突塊,接著蝕刻 去除第2金屬層的柱狀突塊下部以外的部分,直到露出第 -24- (20) 200402812 3金屬層的金屬箔。這時,第1、第3金屬層是銅、銅合 金時,第2金屬層可以用鎳、鎳合金、鈦、鉻、錫、鋅等(57) The first metal layer, the second metal layer, and the third metal layer are layers having mutually different etching conditions. Part of the first metal layer and the second metal layer are removed by etching, and the circuit is formed. The method of manufacturing a wiring board according to item (5 6) formed by removing a part of the third metal layer by etching (58) The semiconductor wafer is mounted on items (38) to (52) or (52) to (57) ) A method of manufacturing a wiring board having one side of a wiring board manufactured by the method described in any one of the following paragraphs, and then sealing a semiconductor wafer mounting surface of the wiring board. The method is as follows (1) to (10) The manufactured wiring board is called wiring board A, the semiconductor package substrate is called semiconductor package substrate A, the semiconductor package described in (13) above is called semiconductor package a, and it is manufactured by the above methods (14) to (19) The semiconductor device is referred to as a semiconductor device B, the substrate described in (22) to (26) above is referred to as a substrate C, and the semiconductor package substrate described in (27) is referred to as a semiconductor package substrate C, (28), (29) ) And (30) are referred to as semiconductor devices Ci, c2, and The semiconductor packages described in C3, (31) and (32) are called semiconductor packages ci and C2, and the wiring boards described in -23- (19) (19) 200402812 (33) to (36) are called wiring boards D, The semiconductor package described in (37) is called a semiconductor package D, the semiconductor package described in (49) to (50) is called a semiconductor package E, and the semiconductor package described in (5) is called a semiconductor package E. [Implementation [Method] <Manufacturing method of wiring board A, substrate A for semiconductor package> The manufacturing method of wiring board A of the present invention includes an insulating member having a plurality of conductive protrusions on its surface, and applying a flowing varnish before hardening by printing. A printing process in which the insulating resin in a state is applied to a thickness where the conductive protrusions are buried by the insulating resin; a hardening process in which the printed insulating resin is hardened; The wiring board A manufactured by the method of the invention includes, for example, a semiconductor package substrate used as an interposer in a semiconductor package, another wiring board such as a semiconductor package or a motherboard on which other electronic components are mounted. A wiring member having a plurality of conductive protrusions on the surface used in the manufacturing method of the wire plate A may be as follows. 1. Metal foil having conductive protrusions on the surface. For example, by using a dry film resist Etching, the first metal layer of the three-layer metal foil of the three-layer metal foil with a metal layer having a different etching condition from that of the second metal layer, the metal foil of a columnar bump, and the resistance of Etching of the etchant makes the first metal layer of the three metal foils into columnar bumps, and then removes the portion other than the lower portion of the columnar bumps of the second metal layer until the 24th (20) 200402812 3 is exposed. Metal layer of metal foil. In this case, when the first and third metal layers are copper or copper alloy, nickel, nickel alloy, titanium, chromium, tin, zinc, etc. can be used as the second metal layer.

2 ·由具有導電性突起的導體與絕緣樹脂構成之配線構 件。例如,配線構件是絕緣樹脂層、絕緣樹脂層兩面上的 層間連接之導體層、及在絕緣樹脂層的至少一面上有導電 性突起者。例如,在上述金屬箔露出柱狀突塊的端面而形 成樹脂層者的樹脂層形成面,加熱壓接上述3層金屬箔, 然後,同樣使第1金屬層成爲柱狀突塊者。同時包含,在 一般的雙面配線板的表面印刷銀糊漿等之導電性糊漿,形 成導電性突起者,使用電鍍抗蝕劑等,藉電鍍析出形成金 屬突起者。 3 .內設元件型的半導體封裝,或配線板的中間構件。 本發明所使用的絕緣樹脂的例子有:聚醯亞胺樹脂、2 · A wiring member composed of a conductive conductor and an insulating resin. For example, the wiring member is an insulating resin layer, a conductor layer for interlayer connection on both surfaces of the insulating resin layer, and a conductive protrusion on at least one surface of the insulating resin layer. For example, on the resin layer forming surface of the metal foil where the end surfaces of the columnar bumps are exposed to form a resin layer, the three metal foils are heated and pressure-bonded, and then the first metal layer is similarly a columnar bump. Also included are those in which a conductive paste such as a silver paste is printed on the surface of a general double-sided wiring board to form a conductive protrusion, and a plating resist is used to deposit metal protrusions by plating. 3. Built-in type semiconductor package or intermediate member of wiring board. Examples of the insulating resin used in the present invention are: polyimide resin,

聚醯胺醯亞胺樹脂、矽樹脂、酚樹脂、雙馬來醯亞胺三氮 雜苯樹脂、環氧樹脂、丙烯樹脂等熱硬化性樹脂,聚苯撐 硫醚樹脂、感光性聚醯亞胺樹脂、丙烯環氧樹脂、乙烯、 丙烯、苯乙烯、丁二烯等熱可塑性彈性體,液晶聚合物等 。也可以使用在此等樹脂混合有機粒子或無機粒子者。用 以混合在樹脂的有機粒子的例子有:上述樹脂的硬化物, 無機粒子的例子有:氧化鋁粒子、二氧化矽、玻璃纖維等 。此等有機或無機粒子的粒徑,最好是平均粒徑〇 . 1〜2 〇 μπι 者。 在本發明是,藉由印刷,在配線構件的具有導電性突 -25- 5 (21) (21)200402812 起的表面,塗抹硬化前的流動狀淸漆狀態的絕緣樹脂,塗 抹到導電性突起被絕緣樹脂埋沒的厚度。流動狀淸漆狀態 的絕緣樹脂,印刷時其黏度最好在3〜70 Pa · s。印刷方 法有:網目掩罩、金屬掩罩等的掩罩印刷法;使用擠壓機 、刀片等直接在配線構件上留下刮痕或空隙而塗抹厚度均 勻的樹脂的方法;及在滾筒或平板等塗抹樹脂後,將樹脂 轉印到配線構件上等方法。而在真空下進行這種作業時, 對減少未塡充部位很有效。 可以在印刷製程後、硬化製程後進行硏磨製程。也可 以在硏磨製程後進行硬化製程。這個時候,是在硏磨製程 之前,進行將絕緣樹脂乾燥到失去流動性,但是在完全硬 化以前之半硬化狀態的乾燥製程,接著進行,硏磨乾燥到 半硬化狀態的絕緣樹脂使導電性突起的前端露出的硏磨製 程,然後進行,令絕緣樹脂完全硬化的硬化製程。這種後 者的方法因樹脂較完全硬化的樹脂軟,可以提高硏磨效率 〇 可以依形成絕緣樹脂層的配線構件改變各層的樹脂調 配成分、樹脂種類、厚度、或層數,控制整體的翹曲量。 絕緣樹脂可以僅用一種以形成單層的樹脂層,也可以使用 ,包括兩種以上的絕緣樹脂、同一組成的樹脂而改變塡充 物等之塡充率者,以形成多層絕緣樹脂層。.同時,如果是 採用多層樹脂層,可以配合構件種類、表面狀態選擇第1 層樹脂,使其成爲接合性良好的一層。 例如,在配線構件的具有導電性突起的面,印刷呈流 -26- (22) (22)200402812 動狀淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性,但是 在完全硬化以前之半硬化狀態,再按順序分別印刷,成分 與絕緣樹脂(1)不同,呈流動狀的淸漆狀態的絕緣樹脂(2) ’及成分與絕緣樹脂(2)不同,呈流動狀的淸漆狀態的絕 緣樹脂(3)之至少兩種絕緣樹脂,乾燥到失去流動性,但 是在完全硬化以前之半硬化狀態,藉此將由絕緣樹脂(i) 層、絕緣樹脂(2 )層及絕緣樹脂(3 )層之至少3層所構成的 多層絕緣樹脂層’形成爲導電性突起被絕緣樹脂埋沒的厚 度。然後’在硏磨製程之前或之後進行硬化製程,令多層 絕緣樹脂層中的所有絕緣樹脂同時完全硬化。 最好是進行,1)將與配線材料的接合性良好的樹脂 ’以硬化前的具流動性的淸漆狀態塗抹一薄層,塗抹後, 將其乾燥到不具流動性的未完全硬化的半硬化狀態,使其 成第1層的製程;2)在不具流動性的半硬化狀態的第1 層的樹脂層上面,以未硬化前的淸漆狀態的液狀,塗抹調 配成不會發生翹曲或波浪的樹脂,同樣將其乾燥到不具流 動性的未完全硬化的半硬化狀態,使其成第2層的製程; 3 )爲了取得樹脂層的平衡,以流動狀的淸漆狀態在第2 層上塗抹與第1層相同或不相同的樹脂,塗抹後,將其乾 燥到不具流動性的未完全硬化的半硬化狀態,使其成第3 層的製程;4)使半硬化狀態的所有樹脂整體硬化成完全 硬化的狀態的製程。 * 一般來講,要使樹脂成爲低收縮,低膨脹率時,是以 高比率混合無機粒子,但樹脂與構件的接合力會降低。因 -27- (23) (23)200402812 此,使接合界面的第1層爲不含無機粒子,或僅含少量, 例如在絕緣樹脂中僅含1〜2 0重量°/。的樹脂層,第2層 則是以較第1層爲高的比率,例如絕緣樹脂中含2 0重量 %以上90重量 %以下的比率混合無機粒子的樹脂層。由 於如此’便能以接合性良好的狀態形成低收縮,低膨脹率 的樹脂層。多層絕緣樹脂層是3層時,第3層使用跟第1 層同樣的絕緣樹脂較佳。 同時’本發明也可以利用作爲,通過設有任意開口的 型版掩罩(stencill mask)印刷含有很多無機、有機粒子等 塡充成分的樹脂,再乾燥之,藉由返覆印刷與乾燥,使在 絕緣樹脂中的任意部位混合存在無機、有機粒子成分的方 法。這時,使用同一樹脂對提高各層間的密接性有幫助。 在硏磨製程的硏磨方法有:滾筒紙硏磨、噴砂法、磨 石粉硏磨、拋光等,使用刀刃的機械加工法,例如銑床加 工也可以。因爲是在半硬化狀態對絕緣樹脂進行硏磨,因 此其硬度較硬化狀態時低,可以提高硏磨效率。 再者’所述的樹脂之半流動狀態是指失去流動性,但 是硬化到可硏磨的狀態,未完全硬化以前之樹脂的狀態。 熱硬化性樹脂稱作B階段(B stage),雖因樹脂而異,但 是指硬化率30〜80 %者。此硬化率可以藉由DSC (示差掃 描熱分析)測量。絕緣樹脂的乾燥到半乾燥狀態,及完全 硬化,如果絕緣樹脂是熱硬化樹脂時,是以加熱法爲之, 回到硏磨時之室溫(5〜35 °C )之狀態時,無流動性,加上 外力時發生彈性變形或塑性變形,去掉外壓時彈性變形時 -28- (24) (24)200402812 會回到原來的狀態,塑性變形時則維持變形的狀態。 溶劑稀釋型的熱可塑性材料時,藉由適度去除溶劑分 ,便可以使其成爲半硬化狀態。去除溶劑分的方法有加熱 或減壓的方法。與熱硬化性樹脂一樣,可硏磨的狀態是, 無流動性,加上外力時發生彈性變形或塑性變形,去掉外 壓時彈性變形時會回到原來的狀態,塑性變形時則維持變 形的狀態。 使用感光性聚醯亞胺等感光性樹脂時,可以藉由照射 紫外線量控制硬化量。使用感光性樹脂時,可以遮蔽導電 性突起上部使紫外線照不到,藉由導電性突起部以外部分 的紫外線照射量減低紫外線照射量,使導電性突起上部較 其他部分爲未硬化的狀態,如此便可以集中硏磨導電性突 起上部,提高硏磨效率。而且,如果此感光性樹脂是可以 藉由藥液去除曝光部分及以外部分的型式,則可以分別以 不同的紫外線照射量照射導電性突起上部與其餘部分,而 僅以藥液去除導電性突起上部的樹脂,藉此可以不硏磨, 或稍許的硏磨便可以使導電性突起上部的前端露出。 同時’藉由本發明方法,使用表面有導電性突起的金 屬范製造半導體封裝用基板A時,可以選擇性蝕刻表面 的金屬箔的薄片狀部分以形成電路圖案。同時,可以在金 屬范的具有導電性突起的表面的平坦部搭載半導體晶片, 連同導電性突起一倂埋入絕緣樹脂中。同時,可以在半導 體封裝用基板A的露出導電性突起的端面之面或電路面 ’再堆疊半導體封裝用基板,使成多層架構的半導體封裝 -29 - (25) (25)200402812 用基板A。 〈半導體封裝A〉 本發明的半導體封裝A使用本發明方法製成的半導 體封裝用基板A。例如’在半導體封裝用基板a的具有電 路圖案的面上,藉由晶片焊接材等固定半導體晶片,以,線 焊接法焊接電路圖案與半導體晶片,或以倒裝晶片法焊接 半導體晶片與電路圖案連接。接者,以密封材密封半導_ 封裝用基板的半導體晶片搭載面,而獲得半導體封裝A。 〈內設元件型的配線板B的製造方法〉 本發明的內設元件型的配線板B的製造方法是,將電 子零件安裝於配線板後,藉由印刷塗抹硬化前的流動狀淸 漆狀態的絕緣樹脂埋沒電子零件,令印刷的絕緣樹脂硬化 ,形成絕緣樹脂層,而在絕緣樹脂層上設配線。電子零件 可以使用半導體晶片,被動零件等,不受限制。配線板可 以使用包含本發明方法製成的配線板A的各種配線板。 同時,跟配線板的製造方法一樣,絕緣樹脂層可以是單層 ,也可以是多曾絕緣樹脂層。可使用的樹脂與配線板A 的製造方法所述者相同。 例如’首先’在配線構件的電子零件安裝面,印刷呈 流動狀淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性,但 是在完全硬化以前之半硬化狀態,再按順序分別印刷,成 分與絕緣樹脂(1 )不同,呈流動狀的淸漆狀態的絕緣樹脂 (26) (26)200402812 (2) ’及成分與絕緣樹脂(2)不同,呈流動狀的淸漆狀態的 絕緣樹脂(3)的至少兩種絕緣樹脂,乾燥到失去流動性, 但是在完全硬化以前之半硬化狀態,藉此將由絕緣樹脂 (1)層、絕緣樹脂(2)層及絕緣樹脂(3)層之至少3層所構成 的多層絕緣樹脂層,形成爲導電性突起被絕緣樹脂埋沒的 厚度。然後進行,令多層絕緣樹脂層中的所有絕緣樹脂同 時完全硬化的硬化製程,以及,在多層絕緣樹脂層上設配 線的製程。 〈基板C〉 第4圖表示本發明的基板C的一實施形態的截面圖。 複數個層間連接用的金屬柱103埋設在絕緣樹脂層106中 ’貫穿到絕緣樹脂層1 06的兩面。各金屬柱1 〇3的直上方 的絕緣樹脂層1 〇 6 —面上,形成有由金屬層構成的電路 111,連接用墊101設在金屬柱103直上方的電路111上 。亦即,金屬柱1 0 3直上方的電路1 1 1被用作連接用墊。 在金屬柱1 0 3的形成電路1 1 1的面的反面的端面,形成有 成爲焊錫突塊等的外部連接用墊(例如,焊錫突塊用墊)的 電路。露出在電路111的表面及基板的相反面的金屬柱 1〇3端面(電路)可視需要施加Ni / Αιι電鍍109、鎳/焊錫 電鍍、鍍銅、鍍銀等。金屬柱1 03與電路1 1 1是藉由蝕刻 金屬箱而形成,層間連接部被金屬柱1 0 3的金屬完全埋沒 。如第4圖所示,通常,本發明的基板C具有複數個由金 屬層構成的層間連接部,但僅設一個也可以。電路可以在 -31 - (27) (27)200402812 層間連接樹脂層的一面,也可以在兩面。可以在金屬柱的 直上部,也可以是從金屬柱的表面向絕緣樹脂層表面突出 的形狀。同時,可以有從金屬柱或貫穿孔電鍍等的層間連 接部直上方布放,前端部設連接用墊的電路。 藉由蝕刻形成金屬柱的金屬箔,可以是一種金屬層構 成的單層金屬箔,也可以是具有兩種以上的金屬層的多層 金屬箔。 金屬柱直上方的電路可以是形成在金屬柱上的金屬層 ,或金屬柱的露出面。 電路是金屬柱的露出面時,本發明的基板C可以藉由 ,例如,使用由絕緣樹脂薄膜或絕緣樹脂板等所成的載體 層,及金屬層所成的金屬箔,蝕刻金屬箔,在載體層上形 成金屬柱,接著,設絕緣樹脂層使金屬層埋沒在絕緣樹脂 中而金屬柱的前端面露出,然後剝離載體層,而製成。同 時。如果載體層是金屬層時,可以在將金屬柱埋入絕緣樹 脂中後,藉由蝕刻去除載體層。 電路是形成在金屬柱上的金屬層時,可以蝕刻一片單 層或多層金屬箔形成電路與金屬柱,也可以分開個別形成 電路與金屬柱。例如,從一片單層或多層金屬箔形成金屬 柱而埋入絕緣樹脂中後,在絕緣樹脂層上堆疊別的金屬箔 ,蝕刻後形成電路也可以。 電路是形成在金屬柱上的金屬層時,例如,可以如下 述,蝕刻一片金屬箔形成電路與金屬柱。 例如,本發明的基板C可以使用:第1金屬層;蝕刻 -32- (28) (28)200402812 條件與第1金屬層不相同的第2金屬層構成的金屬箔;及 絕緣樹脂製成。首先’選擇性鈾刻此金屬范的第1金屬層 ,直到第2金屬層露出’而在第2金屬層上形成可以成爲 金屬柱的第1金屬突塊。接著’在第2金屬層之形成第1 金屬突塊的面上,形成絕緣樹脂層’使第1金屬突塊埋沒 在絕緣樹脂中而其前端面露出。接著’選擇性蝕刻去除第 2金屬層,在金屬柱的直上方形成電路。所謂蝕刻條件不 相同的金屬是指,對一種蝕刻液’有浸蝕性高的金屬與低 的金屬,或各具有對不同蝕刻液的不同浸鈾性的金屬。也 可以在第2金屬層上配設可以在形成絕緣樹脂後加以剝離 的補強用絕緣樹脂薄膜、絕緣樹脂板等之載體層。 又,金屬箔可以使用:第1余屬層;蝕刻條件與第1 金屬層不相同的第2金屬層;及第2金屬層上的蝕刻條件 與第2金屬層不相同的第3金屬層構成。這時,首先,與 上述同樣,選擇性鈾刻金屬范的第1金屬層,在第2金屬 層上形成第1金屬突塊,接著,選擇性蝕刻金屬箔的第2 金屬層’形成可以成爲第1金屬及第2金屬層構成的金屬 柱的金屬突塊。接著,在金屬箔的形成突塊的面上,形成 使金屬突塊埋沒在絕緣樹脂中而其前端面露出的絕緣樹脂 層’接著,選擇性蝕刻第3金屬層,形成電路。 或者’金屬箔可以使用:第〗金屬層;蝕刻條件與第 1金屬層不相同的第2金屬層;及第2金屬層上的蝕刻條 件與第2金屬層不相同的第3金屬層構成,形成由第丨金 屬層構成的金屬柱,及第2金屬層與第3金屬層構成的電 • 33 - (29) 200402812 路。這時’首先,選擇性蝕刻金屬箔的第1金屬層,在第 2金屬層上形成可以成爲金屬柱的第1金屬突塊,接著, 在第2金屬層之形成第1金屬突塊的面上,形成可使第1 金屬突塊埋沒在絕緣樹脂中而其前端面露出的絕緣樹脂層 。接著,分別選擇性蝕刻第3金屬層及第2金屬層,形成 電路。Thermosetting resins such as polyamidoamine imine resin, silicone resin, phenol resin, bismaleimide triazabenzene resin, epoxy resin, acrylic resin, polyphenylene sulfide resin, and photosensitive polyamido Thermoplastic elastomers such as amine resins, propylene epoxy resins, ethylene, propylene, styrene, butadiene, and liquid crystal polymers. It is also possible to use those resins mixed with organic particles or inorganic particles. Examples of the organic particles mixed with the resin include hardened products of the above resins, and examples of the inorganic particles include alumina particles, silica, glass fibers, and the like. The particle diameter of these organic or inorganic particles is preferably an average particle diameter of 0.1 to 2 μm. In the present invention, the surface of the wiring member having conductive protrusions from 25-5 (21) (21) 200402812 is applied by printing, and the insulating resin in a flow-like varnished state before curing is applied to the conductive protrusions. Thickness buried by insulating resin. The insulating resin in the state of flowing varnish should have a viscosity of 3 ~ 70 Pa · s during printing. Printing methods include: mask printing methods such as mesh masks, metal masks, etc .; methods such as using an extruder, a blade, etc. to directly leave scratches or voids on the wiring members and apply a uniform thickness of resin; and using a roller or a flat plate After the resin is applied, the resin is transferred to the wiring member. However, it is effective to reduce unfilled parts when performing this operation under vacuum. The honing process can be performed after the printing process and after the hardening process. The hardening process can also be performed after the honing process. At this time, before the honing process, the insulating resin is dried to lose its fluidity, but the semi-hardened state before it is completely hardened is dried. Then, the honing and drying to the semi-hardened state of the insulating resin makes the conductive protrusion. The honing process in which the front end of the substrate is exposed is then carried out to harden the insulating resin completely. This latter method can improve the honing efficiency because the resin is softer than the completely hardened resin. The resin composition, resin type, thickness, or number of layers can be changed according to the wiring member forming the insulating resin layer to control the overall warpage. the amount. The insulating resin may be formed of only one resin layer to form a single-layer resin layer, or may include two or more insulating resins and resins of the same composition to change the filling rate of the filling material to form a multilayer insulating resin layer. At the same time, if multiple resin layers are used, the first layer of resin can be selected in accordance with the type of component and surface condition to make it a layer with good adhesion. For example, on the surface of the wiring member with conductive protrusions, an insulating resin (1) in the state of flowing varnish -26- (22) (22) 200402812 is printed and dried until it loses fluidity, but it is Semi-hardened state, and then printed separately in sequence. The composition is different from the insulating resin (1), and the insulating resin (2) 'in a flowing varnished state and the composition is different from the insulating resin (2), and is in a flowing varnished state. At least two kinds of insulating resin (3) are dried to lose fluidity, but in a semi-hardened state before being completely hardened, whereby the insulating resin (i) layer, the insulating resin (2) layer and the insulating resin (3 The multilayer insulating resin layer ′ including at least three layers of) layers is formed to a thickness where the conductive protrusions are buried in the insulating resin. Then, a hardening process is performed before or after the honing process, so that all the insulating resins in the multilayer insulating resin layer are completely hardened at the same time. It is best to carry out 1) apply a thin layer of resin with good adhesion to the wiring material in the state of flowable varnish before curing, and after application, dry it to a semi-hardened semi-hardened fluidity Hardened state to make it into the first layer process; 2) On the resin layer of the first layer in the semi-hardened state without fluidity, apply the liquid state of the lacquer state before the hardening, so that it will not warp Curved or wavy resins are also dried to a semi-hardened state that is not fully hardened without fluidity, so that it becomes the second layer process; 3) In order to achieve the balance of the resin layer, the state of the liquid varnish is used in the first layer. The second layer is coated with the same or different resin as the first layer. After application, it is dried to a semi-hardened state with incomplete hardening without fluidity, so that it becomes the process of the third layer; 4) The semi-hardened state A process in which all resins are hardened to a fully hardened state. * In general, to reduce the resin's shrinkage and low expansion rate, the inorganic particles are mixed at a high ratio, but the bonding force between the resin and the member will decrease. Because of -27- (23) (23) 200402812 Therefore, the first layer of the bonding interface is free of inorganic particles, or contains only a small amount, for example, it contains only 1 to 20 weight ° / in the insulating resin. The second layer has a higher ratio than the first layer, for example, a resin layer containing inorganic particles in a ratio of 20% by weight to 90% by weight of the insulating resin. Because of this', a resin layer with low shrinkage and low expansion rate can be formed in a state of good bonding. When the multilayer insulating resin layer is three layers, it is preferable to use the same insulating resin as the first layer for the third layer. At the same time, the present invention can also be used to print a resin containing many inorganic and organic particles and other filling components through a stencill mask provided with any opening, and then dry it. By repeating printing and drying, A method in which inorganic and organic particle components are mixed in any part of the insulating resin. In this case, using the same resin can help improve the adhesion between the layers. The honing methods in the honing process include: roller paper honing, sandblasting, grinding stone honing, polishing, etc. The machining method using a blade edge, such as milling machine processing, can also be used. Because the insulating resin is honed in the semi-hardened state, its hardness is lower than in the hardened state, which can improve the honing efficiency. In addition, the semi-flowing state of the resin means a state where the fluidity is lost, but the resin is hardened to a honable state, and the resin is not completely hardened. The thermosetting resin is called B stage, and although it varies depending on the resin, it means a curing rate of 30 to 80%. This hardening rate can be measured by DSC (Differential Scanning Thermal Analysis). The insulating resin is dried to a semi-dry state and completely hardened. If the insulating resin is a thermosetting resin, the heating method is used. When it returns to the state of room temperature (5 ~ 35 ° C) during honing, there is no flow. In addition, elastic deformation or plastic deformation occurs when external force is added, and when the elastic deformation is removed under external pressure, -28- (24) (24) 200402812 will return to the original state, and the deformed state is maintained during plastic deformation. In the case of a solvent-thinning thermoplastic material, it can be made into a semi-hardened state by appropriately removing the solvent. The solvent can be removed by heating or reducing the pressure. Like thermosetting resin, the state that can be honing is no fluidity, and elastic or plastic deformation occurs when external force is applied. When the external pressure is removed, the elastic deformation will return to the original state, and the plastic deformation will remain deformed. status. When a photosensitive resin such as photosensitive polyimide is used, the amount of hardening can be controlled by the amount of ultraviolet radiation. When using a photosensitive resin, the upper part of the conductive protrusions can be shielded from ultraviolet rays. The amount of ultraviolet radiation can be reduced by the amount of ultraviolet radiation outside the conductive protrusions, so that the upper portion of the conductive protrusions is uncured compared to other parts. Then, the upper part of the conductive protrusion can be honing intensively, and the honing efficiency can be improved. In addition, if the photosensitive resin is a type that can remove the exposed part and other parts by the chemical solution, the upper part of the conductive protrusion and the remaining part can be irradiated with different ultraviolet irradiation amounts, and only the upper part of the conductive protrusion can be removed by the chemical solution With this, the front end of the upper portion of the conductive protrusion can be exposed without honing, or with a little honing. At the same time, by the method of the present invention, when a substrate A for semiconductor package is manufactured using a metal having a conductive protrusion on the surface, a sheet-like portion of the metal foil on the surface can be selectively etched to form a circuit pattern. At the same time, a semiconductor wafer can be mounted on a flat portion of the surface of the metal having conductive protrusions, and the semiconductor wafer can be buried in the insulating resin together with the conductive protrusions. At the same time, the semiconductor package substrate can be stacked on the surface of the semiconductor package substrate A that exposes the conductive protrusion's end surface or the circuit surface ', so that the semiconductor package having a multilayer structure can be used. -29-(25) (25) 200402812 The substrate A can be used. <Semiconductor package A> The semiconductor package A of the present invention uses a semiconductor package substrate A produced by the method of the present invention. For example, 'on a surface of the semiconductor package substrate a having a circuit pattern, a semiconductor wafer is fixed by a wafer bonding material or the like, and the circuit pattern and the semiconductor wafer are bonded by wire bonding, or the semiconductor wafer and the circuit pattern are bonded by flip chip bonding. connection. Then, the semiconductor wafer mounting surface of the semiconductor package substrate is sealed with a sealing material to obtain a semiconductor package A. <Manufacturing method of the built-in type wiring board B> The manufacturing method of the built-in type wiring board B of the present invention is that after the electronic components are mounted on the wiring board, the flowing varnished state before curing is applied by printing. The insulating resin is buried in the electronic parts to harden the printed insulating resin to form an insulating resin layer, and wiring is provided on the insulating resin layer. Electronic parts can use semiconductor wafers, passive parts, etc. without restrictions. As the wiring board, various wiring boards including the wiring board A produced by the method of the present invention can be used. At the same time, like the manufacturing method of the wiring board, the insulating resin layer may be a single layer or a multi-layer insulating resin layer. The resin that can be used is the same as that described in the production method of the wiring board A. For example, 'first', on the mounting surface of the electronic component of the wiring member, print the insulating resin (1) in the state of flowing varnish and dry it until it loses fluidity. Unlike the insulating resin (1), the insulating resin (26) (26) 200402812 (2) 'and the composition is different from the insulating resin (2). 3) at least two kinds of insulating resins are dried to lose fluidity, but in a semi-hardened state before being completely hardened, whereby at least two layers of insulating resin (1), insulating resin (2), and insulating resin (3) are used. The multilayer insulating resin layer composed of three layers is formed to a thickness where the conductive protrusions are buried in the insulating resin. Then, a hardening process is performed in which all the insulating resins in the multilayer insulating resin layer are completely hardened at the same time, and a process of providing a wiring on the multilayer insulating resin layer is performed. <Substrate C> FIG. 4 is a cross-sectional view showing an embodiment of a substrate C of the present invention. A plurality of metal pillars 103 for interlayer connection are buried in the insulating resin layer 106 'and penetrate through both sides of the insulating resin layer 106. A circuit 111 made of a metal layer is formed on the insulating resin layer 106 directly above each metal pillar 103, and a connection pad 101 is provided on the circuit 111 directly above the metal pillar 103. That is, the circuit 1 1 1 directly above the metal pillar 103 is used as a connection pad. A circuit of an external connection pad (for example, a pad for a solder bump) serving as a solder bump or the like is formed on an end surface of the metal pillar 103 that is opposite to a surface on which the circuit 1 11 is formed. The metal pillars 103 exposed on the surface of the circuit 111 and the opposite surface of the substrate (circuit) may be applied with Ni / Aluminum plating 109, nickel / solder plating, copper plating, silver plating, etc. as required. The metal pillar 103 and the circuit 111 are formed by etching a metal box, and the interlayer connection portion is completely buried by the metal of the metal pillar 103. As shown in Fig. 4, generally, the substrate C of the present invention has a plurality of interlayer connection portions made of a metal layer, but only one may be provided. The circuit can be connected to one side or both sides of the resin layer between layers -31-(27) (27) 200402812. The shape may be a straight upper part of the metal pillar, or a shape protruding from the surface of the metal pillar to the surface of the insulating resin layer. At the same time, there may be a circuit in which an interlayer connection portion such as a metal pillar or a through-hole plating is arranged directly above, and a connection pad is provided at the front end portion. The metal foil that forms the metal pillars by etching may be a single-layer metal foil composed of one metal layer or a multilayer metal foil having two or more metal layers. The circuit directly above the metal pillar can be a metal layer formed on the metal pillar or the exposed surface of the metal pillar. When the circuit is the exposed surface of a metal pillar, the substrate C of the present invention can be etched by using a carrier layer made of an insulating resin film or an insulating resin plate, and a metal foil made of a metal layer, for example. A metal pillar is formed on the carrier layer. Next, an insulating resin layer is provided so that the metal layer is buried in the insulating resin and the front end surface of the metal pillar is exposed, and then the carrier layer is peeled off to make it. Simultaneously. If the carrier layer is a metal layer, after the metal pillar is buried in the insulating resin, the carrier layer can be removed by etching. When a circuit is a metal layer formed on a metal pillar, a single or multiple layers of metal foil can be etched to form the circuit and metal pillar, or the circuit and metal pillar can be formed separately. For example, after forming a metal pillar from a single-layer or multi-layer metal foil and burying it in an insulating resin, another metal foil is stacked on the insulating resin layer, and a circuit may be formed after etching. When the circuit is a metal layer formed on a metal pillar, for example, a piece of metal foil can be etched to form the circuit and the metal pillar as described below. For example, the substrate C of the present invention can be made of: a first metal layer; etching -32- (28) (28) 200402812 a metal foil composed of a second metal layer having conditions different from those of the first metal layer; and an insulating resin. First, the first metal layer of this metal range is "selectively uranium-etched until the second metal layer is exposed", and a first metal bump that can be a metal pillar is formed on the second metal layer. Next, "the insulating resin layer is formed on the surface of the second metal layer where the first metal bump is formed" so that the first metal bump is buried in the insulating resin and its front end surface is exposed. Next, the second metal layer is removed by selective etching to form a circuit directly above the metal pillar. The metals having different etching conditions refer to metals having high etchability and low metals to one etchant ', or metals having different uranium immersion properties to different etching solutions. A carrier layer such as a reinforcing insulating resin film or an insulating resin plate that can be peeled off after the insulating resin is formed may be disposed on the second metal layer. In addition, the metal foil may include a first remaining metal layer, a second metal layer having different etching conditions from the first metal layer, and a third metal layer having a different etching condition from the second metal layer. . At this time, first, as described above, the first metal layer of the metal layer is selectively etched with uranium, and a first metal bump is formed on the second metal layer. Then, the second metal layer is selectively etched to form a second metal layer. A metal bump of a metal pillar composed of one metal and a second metal layer. Next, an insulating resin layer 'is formed on the surface of the metal foil on which the bumps are formed, in which the metal bumps are buried in the insulating resin and the front end surface is exposed. Next, the third metal layer is selectively etched to form a circuit. Alternatively, 'metal foil can be used: a first metal layer; a second metal layer having different etching conditions from the first metal layer; and a third metal layer having different etching conditions from the second metal layer, Form a metal pillar composed of the first metal layer, and an electrical circuit composed of the second metal layer and the third metal layer. • 33-(29) 200402812. At this time, 'first, the first metal layer of the metal foil is selectively etched to form a first metal bump which can be a metal pillar on the second metal layer, and then, on the surface where the first metal bump is formed on the second metal layer An insulating resin layer can be formed in which the first metal bump is buried in the insulating resin and the front end surface thereof is exposed. Next, the third metal layer and the second metal layer are selectively etched to form a circuit.

不論是那一種方法,同時可以再形成從金屬柱上部布 放,前端有連接用突塊的電路。最好在形成絕緣樹脂層之 前’在形成有金屬箔的金屬突塊之面上,施加可以使跟絕 緣樹脂的密接性較佳的表面處理。表面處理可以有:化學 磷系處理、化學磷酸系處理、化學蟻酸系處理、藉電解賦 予金屬粒等。Regardless of which method, a circuit can be formed from the top of the metal post with a connection bump at the front end. Before forming the insulating resin layer, it is preferable to apply a surface treatment to the surface of the metal bumps on which the metal foil is formed, which can improve the adhesion with the insulating resin. The surface treatment may include: chemical phosphorus-based treatment, chemical phosphoric acid-based treatment, chemical formic acid-based treatment, and metal particles imparted by electrolysis.

第1金屬可以使用從銅、銅合金、鐵、鎳合金等選擇 者。第2金屬在第1金屬是銅或銅合金時,可以使用鎳、 鎳合金、鈦、鉻、錫、鋅、金等,第1金屬是鐵或鎳合金 時,可以使用鈦、鉻、錫等。第3金屬可以使用從銅、銅 合金、鐵、鎳合金等選擇者。 形成金屬柱的第1金屬的厚度最好是12〜100 μπι, 超過100 μπι時,形成金屬突塊時的蝕刻準確度低,要形 成細緻的圖案可能很困難,而不足1 2 μιη時,則有可能使 金屬柱的強度不充分,或絕緣樹脂的絕緣性降低。更好是 18〜70 μπι。第2金屬的厚度最好是0.05〜50 μπι,超過 5 0 μηι時,形成金屬突塊時的蝕刻準確度低,要形成細緻 的圖案可能很困難,而不足0.05 μιη時,蝕刻第1金屬層 -34- (30) (30)200402812 時,因爲第2金屬層產生的凹坑或缺口,第3金屬層有被 浸触的可hS。更好是0.1〜35 μπι。第3金屬的厚度取好 是1〜50 μηι,超過50 μιη時,形成金屬突塊時的蝕刻準 確度低,要形成細緻的圖案可能很困難,而不足1 μπι時 ,蝕刻第1金屬時,因爲第2金屬層產生的凹坑或缺口, 第3金屬層有被浸蝕的可能。更好是5〜1 2 μηι。 載體層可以使用絕緣樹脂板、絕緣薄膜、或金屬箔。 絕緣樹脂板可以使用,例如從環氧樹脂、聚醯亞胺樹脂、 矽樹脂、酚樹脂等中所選擇者。絕緣薄膜可以使用,例如 從聚醯亞胺樹脂、聚對苯二酸乙烯樹脂、聚苯撐硫醚薄膜 等中所選擇者。金屬箔可以使用從銅箔、銅合金箔、鐵、 鎳合金等所選.擇者。 絕緣樹脂層所使用的絕緣樹脂材料有:熱硬化性的環 氧樹脂、聚醯亞胺樹脂、矽樹脂、聚醯胺醯亞胺樹脂、聚 苯撐硫醚樹脂、感光性聚醯亞胺樹脂、丙烯環氧樹脂、乙 烯、丙烯、苯乙烯、丁二烯等熱可塑性彈性體,液晶聚合 物等。絕緣樹脂層的厚度,通常是跟蝕刻第1金屬層形成 的金屬柱的高度相同。 金屬柱的形狀是實心的金屬柱,沒有特別限制,通常 是半徑1 0〜7 5 0 μπι的圓柱,短側的一邊的寬度2 〇 μιη以 上的方形等。 本發明的基板C可以是僅具有一層絕緣樹脂層者,也 可以是具有絕緣樹脂層的下面再經由絕緣層堆疊的複數個 導體電路層的多層配線板。 -35- (31) (31)200402812 本發明的基板C可以當作半導體封裝所用的插入基板 ,或當作搭載半導體封裝的電子零件的母板等配線板,在 製造各種半導體裝置時使用。 〈半導體裝置C1及C2〉 例如,在本發明的基板C搭載半導體晶片,在基板C 的金屬柱直上方,以電氣方式連接設於電路上的連接用墊 與半導體晶片的連接用墊,便可以獲得本發明的半導體裝 置C 1或C2。藉由線焊接連接製造半導體裝置C 1時,例 如,以晶片焊接材等將半導體晶片固定搭載於基板C上後 ,在基板C的金屬柱直上方,以金線、鋁線、銅線等導體 引線焊接設於電路上的連接用墊與半導體晶片的連接用墊 。藉由倒裝晶片焊接製造半導體裝置C2時,將形成在半 導體晶片的連接用墊上的金、焊錫、鉛、銅、錫、銀突塊 、及各合金、金屬與樹脂混合的導電性糊漿,向異性導電 薄膜、在無機物或有機物的球塗抹金屬的突塊等金屬突塊 ,在基板C的金屬柱直上方,直接連接在設於電路上的連 接用墊。 〈半導體封裝C1及C2〉 以密封材密封上述半導體裝置C1及C2的半導體搭 載面側,則可獲得本發明的半導體封裝C 1及C2。密封可 以藉由,使用絕緣樹脂的塑模、轉換塑模、罐燒、澆鑄, 使用遮蔽印刷法的樹脂密封等實施。樹脂密封所使用的絕 -36- (32) 200402812 緣樹脂可以使用:環氧樹脂、矽樹脂、酚樹脂、環氧變性 酚樹脂等。The first metal can be selected from copper, copper alloys, iron, and nickel alloys. When the first metal is copper or a copper alloy, nickel, a nickel alloy, titanium, chromium, tin, zinc, gold, or the like can be used. When the first metal is iron or a nickel alloy, titanium, chromium, tin, or the like can be used. . The third metal can be selected from copper, copper alloys, iron, and nickel alloys. The thickness of the first metal forming the metal pillar is preferably 12 to 100 μm. When it exceeds 100 μm, the accuracy of etching when forming the metal bumps is low, and it may be difficult to form a detailed pattern. When it is less than 12 μm, then There is a possibility that the strength of the metal pillar is insufficient, or the insulation of the insulating resin may be reduced. It is more preferably 18 to 70 μm. The thickness of the second metal is preferably 0.05 to 50 μm. When the thickness is more than 50 μm, the accuracy of etching when forming metal bumps is low. It may be difficult to form a detailed pattern. When the thickness is less than 0.05 μm, the first metal layer is etched. -34- (30) (30) 200402812, due to the pits or gaps generated by the second metal layer, the third metal layer has an impregnable hS. More preferably, it is 0.1 to 35 μm. The thickness of the third metal is preferably 1 to 50 μηι. When it exceeds 50 μιη, the accuracy of etching when forming metal bumps is low, and it may be difficult to form a detailed pattern. When it is less than 1 μπι, when etching the first metal, The third metal layer may be etched due to the pits or notches generated by the second metal layer. More preferably, it is 5 to 12 μm. As the carrier layer, an insulating resin plate, an insulating film, or a metal foil can be used. The insulating resin plate may be selected from, for example, epoxy resin, polyimide resin, silicone resin, phenol resin, and the like. The insulating film can be used, for example, a film selected from a polyimide resin, a polyethylene terephthalate resin, and a polyphenylene sulfide film. The metal foil can be selected from copper foil, copper alloy foil, iron, nickel alloy and the like. The insulating resin materials used for the insulating resin layer are: thermosetting epoxy resin, polyimide resin, silicone resin, polyimide resin, polyphenylene sulfide resin, and photosensitive polyimide resin , Propylene epoxy, ethylene, propylene, styrene, butadiene and other thermoplastic elastomers, liquid crystal polymers and so on. The thickness of the insulating resin layer is usually the same as the height of a metal pillar formed by etching the first metal layer. The shape of the metal pillar is a solid metal pillar, which is not particularly limited. Usually, it is a cylinder with a radius of 10 to 750 μm, and a square with a width of 2 μm or more on the short side. The substrate C of the present invention may be a multilayer wiring board having only one insulating resin layer, or a multilayer wiring board having a plurality of conductive circuit layers stacked under the insulating resin layer under the insulating layer. -35- (31) (31) 200402812 The substrate C of the present invention can be used as an interposer substrate for a semiconductor package, or as a wiring board such as a motherboard for mounting electronic components of a semiconductor package, and is used in manufacturing various semiconductor devices. <Semiconductor devices C1 and C2> For example, a semiconductor wafer is mounted on the substrate C of the present invention, and the connection pads provided on the circuit and the connection pads of the semiconductor wafer are electrically connected directly above the metal pillars of the substrate C. A semiconductor device C 1 or C 2 of the present invention is obtained. When the semiconductor device C 1 is manufactured by wire bonding, for example, a semiconductor wafer is fixedly mounted on the substrate C with a wafer bonding material or the like, and a conductor such as a gold wire, an aluminum wire, or a copper wire is directly above the metal pillar of the substrate C A connection pad provided on a circuit and a connection pad for a semiconductor wafer are provided by wire bonding. When the semiconductor device C2 is manufactured by flip-chip bonding, gold, solder, lead, copper, tin, silver bumps, and conductive pastes of various alloys, metals, and resins formed on the connection pads of the semiconductor wafer, Metal bumps, such as anisotropic conductive films and metal bumps coated with balls of inorganic or organic materials, are directly connected to the connection pads provided on the circuit directly above the metal pillars of the substrate C. <Semiconductor packages C1 and C2> By sealing the semiconductor mounting surfaces of the semiconductor devices C1 and C2 with a sealing material, the semiconductor packages C1 and C2 of the present invention can be obtained. Sealing can be carried out by using a mold using an insulating resin, a conversion mold, pot burning, casting, resin sealing using a mask printing method, or the like. Insulation used for resin sealing -36- (32) 200402812 Edge resin can be used: epoxy resin, silicone resin, phenol resin, epoxy modified phenol resin, etc.

第7圖表示本發明的半導體封裝C1的一個例子的截 面圖。金屬柱1 〇 3埋入在基板A的絕緣樹脂層1 0 6中, 貫穿至絕緣樹脂層1 0 6的兩面。在金屬柱1 〇 3直上方,於 絕緣樹脂層1 06的一面上形成有由金屬層構成的電路1 1 1 。露出在絕緣樹脂層1 06下面側的金屬柱1 03的表面,與 電路1 1 1的表面施加有Ni/Αιι電鍍109。搭載於基板C上 的半導體晶片105的連接用墊(未圖示),與設在金屬柱 103直上方的電路之連接用墊ιοί,由金引線107加以線 焊接。基板C的搭載半導體晶片1 〇 5的面由密封材1 〇 8加 以密封。Fig. 7 is a sectional view showing an example of the semiconductor package C1 of the present invention. The metal pillar 103 is embedded in the insulating resin layer 106 of the substrate A, and penetrates to both sides of the insulating resin layer 106. A circuit 1 1 1 made of a metal layer is formed on one side of the insulating resin layer 106 directly above the metal pillar 103. The surface of the metal pillar 103 exposed on the underside of the insulating resin layer 106 is applied with Ni / Aluminum plating 109 to the surface of the circuit 110. A pad (not shown) for connection of the semiconductor wafer 105 mounted on the substrate C and a pad for connection to a circuit provided directly above the metal pillar 103 are wire-bonded by a gold lead 107. The surface of the substrate C on which the semiconductor wafer 105 is mounted is sealed by a sealing material 108.

如第7圖所示,在金屬柱1 03直上方的電路設連接用 墊1 0 1時,可以不必設用以避開層間連接部而布放的配線 ,及與晶片的連接用墊,因此可以達成封裝的小型化。同 時,縱使不必小型化,減少不必要配線的空間可以利用以 加大其他配線的間距。而且,基板上的樹脂表面積增加, 可以推測與其後的密封材或塡底材、抗鈾劑的接合性會較 佳。 同時,其他優點有,連接方法使用線焊接法、或使用 超音波的倒裝晶片連接法時,藉由鈾刻形成的金屬柱直上 方的電路,因爲電路下充滿金屬,較之其他之電路下充滿 樹脂的部位,超音波不容易傳遞。因此穫得,焊接性良好 的結果。 -37- (33) 200402812 關於小型化’則因整體面積減少相當於焊接在金屬柱 直上方的連接用墊的端子數,因此設計時的配線布放有較 充裕的空間。本發明的實施方法非常簡便,設計電路圖案 時,在突塊直上方的電路設突塊即可。 〈半導體裝置C3〉 同時,本發明可以提供,以本發明的基板C當作母基 板等的配線板使用的半導體裝置C 3。此半導體裝置c 3具 有基板C及搭載於基板C的電子零件,電子零件的外部 連接端子,與在基板C的金屬柱直上方設在電路上的連接 用墊,在該連接用墊上連接在一起。電子零件有:半導體 封裝、半導體晶片等。與這種半導體封裝、半導體晶片等 電子零件連接時,也可以獲得與上述同樣的優點。同時, 此半導體裝置C 3也可以密封電子零件搭載面側。As shown in FIG. 7, when a connection pad 101 is provided on a circuit directly above the metal pillar 103, it is not necessary to provide a wiring for avoiding the interlayer connection portion and a connection pad to the chip. Miniaturization of the package can be achieved. At the same time, even if miniaturization is not necessary, the space for reducing unnecessary wiring can be used to increase the distance between other wirings. In addition, the surface area of the resin on the substrate is increased, and it is presumed that the adhesion to the subsequent sealing material, plutonium substrate, and uranium resistance agent is better. At the same time, other advantages are that when the connection method uses a wire bonding method or a flip chip connection method using ultrasonic waves, the circuit formed directly above the metal pillars formed by uranium engraving is because the circuit is full of metal, compared with other circuits. Ultrasonic waves are not easily transmitted in resin-filled areas. As a result, good solderability is obtained. -37- (33) 200402812 Regarding miniaturization, the overall area is reduced, which is equivalent to the number of terminals of the connection pads soldered directly above the metal pillars. Therefore, there is ample space for wiring in the design. The method for implementing the present invention is very simple. When designing a circuit pattern, it is sufficient to provide a bump on the circuit directly above the bump. <Semiconductor device C3> Also, the present invention can provide a semiconductor device C3 using the substrate C of the present invention as a wiring board such as a mother substrate. This semiconductor device c 3 has a substrate C and electronic components mounted on the substrate C, and external connection terminals of the electronic components are connected to a connection pad provided on a circuit directly above a metal pillar of the substrate C, and are connected to the connection pad. . Electronic parts include: semiconductor packages, semiconductor wafers, etc. When connected to such electronic components as semiconductor packages and semiconductor wafers, the same advantages as described above can be obtained. At the same time, this semiconductor device C 3 can also seal the electronic component mounting surface side.

〈配線板D〉 本發明的配線板D具備有:樹脂層·,在樹脂層的至 少一面上的電路;從電路至樹脂層的相反面突出在樹脂層 中的複數個柱狀的外部連接端子,電路及外部連接端子之 與樹脂層接觸的表面,爲了使其與樹脂層的密接性良好, 經過粗化。而電路與樹脂層接觸的層,使甩與樹脂層的密 接性良好的金屬層,或容易粗化的金屬層,較爲理想。 本發明的配線板D可以例如依照本發明方法,使用 具有薄片部及從薄片部的一面突出的複數個柱狀的外部連 -38- (34) (34)200402812 接端子的金屬薄片製造。首先,如第10圖所示,將金屬 薄片的具有外部連接端子X的表面粗化。藉由此項粗化 ,在金屬薄片的薄片部W突出的外部連接端子X的表面 ,與外部連接端子X的表面形成粗化面2 04。接著,在金 屬薄片的經粗化的表面上,形成外部連接端子X露出前 端狀埋沒在絕緣樹脂中的絕緣樹脂層,接著,去除一部分 金屬薄片的薄片部W到樹脂層露出,藉此在樹脂層上形<Wiring board D> The wiring board D of the present invention includes a resin layer, a circuit on at least one side of the resin layer, and a plurality of columnar external connection terminals protruding from the resin layer from the circuit to the opposite side of the resin layer. The surfaces of the circuits and external connection terminals that are in contact with the resin layer are roughened in order to make the adhesion with the resin layer good. The layer in which the circuit contacts the resin layer is preferably a metal layer with good adhesion to the resin layer or a metal layer that is easily roughened. The wiring board D of the present invention can be manufactured, for example, according to the method of the present invention using a sheet of metal having a sheet portion and a plurality of columnar external connections protruding from one side of the sheet portion. (38) (34) 200402812 First, as shown in Fig. 10, the surface of the metal sheet having the external connection terminal X is roughened. By this roughening, the surface of the external connection terminal X protruding from the sheet portion W of the metal foil forms a roughened surface 204 with the surface of the external connection terminal X. Next, on the roughened surface of the metal foil, an external connection terminal X is formed to expose an insulating resin layer whose front end is buried in an insulating resin. Then, a part of the foil portion W of the metal foil is removed until the resin layer is exposed, whereby Layer shape

成與外部連接端子連接的電路,而製成本發明的配線板D 〇 粗化的方法可以採用化學粗化(化學磷系處理、化學 磷酸系處理、化學蟻酸系處理等);機械粗化(噴砂加工等 );電漿處理;藉電解賦予金屬粒等,均可以。 這時,選擇不僅薄片部的外部連接端子突出的表面, 至少外部連接端子的側面也可以同時粗化的條件也是很重 要。 同時,薄片部的外部連接端子突出的表面的金屬,與 外部連接端子的金屬相同時,粗化量會一定,粗化條件的 選擇容易,較理想。同時,如果上述兩者的金屬相同時, 金屬表面與樹脂層的樹脂之接合性成爲較良好的樹脂的選 定也便容易,很理想。 在上述配線板D的製造方法所使用的具有薄片部及 從薄片部的一面突出的複數個柱狀的外部連接端子的金屬 薄片,可以使用,例如,依序具有第1金屬層、第2金屬 層及第3金屬層的至少3層的多層金屬箔製成。亦即’去To form a circuit connected to an external connection terminal, the roughening method of the wiring board D 0 of the present invention can be chemical roughening (chemical phosphorous treatment, chemical phosphoric acid treatment, chemical formic acid treatment, etc.); mechanical roughening (sandblasting) Processing, etc.); plasma treatment; metal particles, etc. can be given by electrolysis. In this case, it is also important to select a condition in which not only the surface of the external connection terminal of the sheet portion protrudes, but also at least the side surface of the external connection terminal can be roughened at the same time. At the same time, when the metal on the protruding surface of the external connection terminal in the thin section is the same as the metal of the external connection terminal, the roughening amount is constant, and the selection of the roughening conditions is easy and ideal. At the same time, if the metals of the above two are the same, it is easy to select a resin having a good adhesion between the metal surface and the resin of the resin layer, which is ideal. The metal sheet having a sheet portion and a plurality of columnar external connection terminals protruding from one surface of the sheet portion used in the method for manufacturing the wiring board D can be used, for example, having a first metal layer and a second metal in this order. And at least three layers of a multilayer metal foil. That ’s going

-39- (35) 200402812 除此多層金屬箔的第1金屬層的一部分,直到露出第2層 的金屬層,而在第2金屬層的露出面形成複數個柱狀外部 連接端子’藉此製成從一面突出複數個柱狀的外部連接端 子的形狀的金屬薄片。這時,第2金屬層是與樹脂層的密 接性很好的金屬層’或很容易粗化的金屬層較佳。-39- (35) 200402812 Except a part of the first metal layer of the multilayer metal foil, until the second metal layer is exposed, a plurality of columnar external connection terminals are formed on the exposed surface of the second metal layer. A metal sheet having a shape in which a plurality of columnar external connection terminals protrude from one side. In this case, it is preferable that the second metal layer is a metal layer having good adhesion to the resin layer 'or a metal layer which is easily roughened.

多層金屬箔使用第1金屬層、第2金屬層及第3金屬 層是鄰接層的鈾刻條件互異的層,藉由鈾刻去除第1金屬 層的一部分,電路之形成是藉由依序蝕刻第1金屬層及第 2金屬層,將其部分性去除便可以形成。The multilayer metal foil uses a first metal layer, a second metal layer, and a third metal layer that are adjacent layers with different uranium etching conditions. A portion of the first metal layer is removed by uranium etching, and the circuit is formed by sequential etching. The first metal layer and the second metal layer can be formed by partially removing them.

同時,上述金屬薄片也可以使用,金屬層的第1層 (1);在第1層的一面上的複數個金屬柱(2);及包含與樹 脂層的密接性很好的金屬層或容易粗化的金屬層,具有形 成在第1層的另一面上的一層以上的金屬層(3)的複合金 屬層製成。例如,將此複合金屬箔的至少一層金屬層,從 第1層依次去除金屬柱下以外的部分,直到露出與樹脂層 的密接性很好的金屬層或容易粗化的金屬層,便可以製作 金屬薄片。 上述方法可以藉由,例如第1 1圖所示的製程實施。 首先,準備依序具有第1金屬層201、第2金屬層202及 第3金屬層203的至少3層的多層金屬箔(第丨!圖(&amp;))。 去除多層金屬箔的第1金屬層201的一部分,直到露出第 2層202的金屬層,而在第2金屬層202的露出面形成複 數個金屬柱Y,獲得上述多層金屬箔(第11(b))。接著, 去除第2金屬層的2〇2金屬柱γ下部分以外的一部分, -40- (36) 200402812At the same time, the above-mentioned metal flakes can also be used. The first layer (1) of the metal layer; a plurality of metal pillars (2) on one side of the first layer; and a metal layer containing a good adhesion to the resin layer or easily The roughened metal layer is made of a composite metal layer having one or more metal layers (3) formed on the other side of the first layer. For example, this composite metal foil can be produced by removing at least one metal layer of the composite metal foil from the first layer in sequence except the metal pillars until a metal layer with good adhesion to the resin layer or a metal layer easily roughened is exposed. foil. The above method can be implemented by, for example, the process shown in FIG. 11. First, a multi-layer metal foil (&amp; FIG.) Having at least three layers of the first metal layer 201, the second metal layer 202, and the third metal layer 203 in this order is prepared. A part of the first metal layer 201 of the multilayer metal foil is removed until the metal layer of the second layer 202 is exposed, and a plurality of metal pillars Y are formed on the exposed surface of the second metal layer 202 to obtain the above-mentioned multilayer metal foil (No. 11 (b )). Next, a part other than the lower part of the 002 metal pillar γ of the second metal layer is removed, -40- (36) 200402812

直到露出第3金屬層20 3,藉此製成具有薄片部(第3金 屬層20 3 )及複數個柱狀的外部連接端子X(由第1金屬層 201及第2金屬層202的金屬形成)的金屬薄片(第n (c)) 。使第3金屬層2 0 3是與樹脂層的密接性很好或很容易粗 化的金屬層,便可以使跟樹脂層的密接性良好或容易粗化 的金屬層露出。粗化此金屬薄片的具有外部連接端子的表 面,形成粗化面204。粗化的方法是如上述,化學粗化( 蝕刻等);機械粗化(噴砂加工等);電漿處理;藉電解賦 予金屬粒等,均可以。Until the third metal layer 20 3 is exposed, a thin portion (the third metal layer 20 3) and a plurality of columnar external connection terminals X (formed from the metal of the first metal layer 201 and the second metal layer 202) are formed. ) Of metal foil (n (c)). When the third metal layer 203 is a metal layer with good adhesion to the resin layer or easily roughened, the metal layer with good adhesion to the resin layer or easily roughened can be exposed. The surface of the metal foil having external connection terminals is roughened to form a roughened surface 204. The roughening methods are as described above, chemical roughening (etching, etc.); mechanical roughening (sandblasting, etc.); plasma treatment; and metal particles imparted by electrolysis, etc., are all acceptable.

又如第12圖所示,去除多層金屬箔的第1金屬層 201的一部分,直到露出第2金屬層202,而在第2金屬 層202的露出面形成複數個金屬柱Y後(第12圖(a)),接 著,如上述去除第2金屬層202的同時,將第3金屬層 2 0 3的露出面及金屬柱Y的表面加以粗化也可以。同時進 行去除及粗化的方法可以採化學粗化(蝕刻等);機械粗化 (噴砂加工等);電漿處理等。此方法適合第2金屬層202 較薄時,可以減少製程。 在上述方法,多層金屬箔是藉由使用第1金屬層、第 2金屬層及第3金屬層是鄰接層的蝕刻條件互異的層,而 藉由蝕刻去除第1金屬層及第2金屬層的一部分,電路之 形成是藉由蝕刻第3金屬層,部分性去除而形成。 粗化量因樹脂層的樹脂種類而異,但以0.3 μηι〜5 μπι前後較佳。 -41 - (37) 200402812 〈半導體封裝D〉As shown in FIG. 12, a part of the first metal layer 201 of the multilayer metal foil is removed until the second metal layer 202 is exposed, and a plurality of metal pillars Y are formed on the exposed surface of the second metal layer 202 (FIG. 12 (A)) Next, the exposed surface of the third metal layer 203 and the surface of the metal pillar Y may be roughened while the second metal layer 202 is removed as described above. The methods for simultaneous removal and roughening can be chemical roughening (etching, etc.); mechanical roughening (sandblasting, etc.); plasma treatment, etc. This method is suitable when the second metal layer 202 is thin, and the manufacturing process can be reduced. In the above method, the multilayer metal foil is a layer in which the etching conditions of the first metal layer, the second metal layer, and the third metal layer are adjacent layers are different from each other, and the first metal layer and the second metal layer are removed by etching. Part of the circuit is formed by etching the third metal layer and partially removing it. The amount of roughening varies depending on the resin type of the resin layer, but it is preferably around 0.3 μm to 5 μm. -41-(37) 200402812 <Semiconductor Package D>

本發明的半導體封裝D,是將本發明的配線板D使用 作爲半導體封裝用基板者,具備有:本發明的配線板D ; 搭載於配線板D的半導體晶片;及用以密封配線板〇的 半導體晶片搭載面的密封材料。本發明的半導體封裝d 是,例如,依照本發明的製造方法,在藉由上述方法製成 的配線板D的具有電路的面上搭載半導體晶片,接著, 密封配線板D的半導體晶片搭載面,則可以製成。The semiconductor package D of the present invention uses the wiring board D of the present invention as a substrate for a semiconductor package, and includes: the wiring board D of the present invention; a semiconductor wafer mounted on the wiring board D; and a substrate for sealing the wiring board. Sealing material for semiconductor wafer mounting surface. In the semiconductor package d of the present invention, for example, according to the manufacturing method of the present invention, a semiconductor wafer is mounted on the circuit-equipped surface of the wiring board D manufactured by the above method, and then the semiconductor wafer mounting surface of the wiring board D is sealed. It can be made.

第13圖表示本發明之半導體封裝0的製造方法的一 個形態。準備具有薄片部W、從薄片部W的一面突出的 複數個外部連接端子X的金屬薄片,將金屬薄片的具有 外部連接端子X的表面加以粗化(第13(a))。接著,在表 面粗化的金屬薄片的粗化的表面上塗抹樹脂2 0 5,而埋入 外部連接端子X(第13圖(b))。硏磨塗在金屬薄片的樹脂 2 05 ’直到外部連接端子X的前端露出,而形成樹脂層z (第1 3圖(c))。去除樹脂層Z上的一部分薄片部W,直到 露出樹脂層z,藉此在樹脂層Z上形成與外部連接端子X 連接的電路206,獲得本發明的配線板D(第13圖(d))。 在電路206的表面及外部連接端子X的露出的端面,視 需要施加鎳/金電鍍207、鎳/焊錫電鍍、鍍銅、鍍銀等 (第13圖(e))。在配線板D的具有電路206的面上,黏貼 晶片焊接薄膜2 0 8,再黏貼半導體晶片20 9(第13圖(f))。 用金引線210、鋁線、銅線等導體引線線焊接電路206的 連接用墊與半導體晶片209的連接用墊,將半導體晶片 -42- (38) (38)200402812 209搭載於配線板D(第13圖(g))。接著,以密封材211 密封配線板D的半導體晶片搭載面,在外部連接端子X 的露出面接合焊錫球212,而獲得半導體封裝D(第13圖 (h))。 再者,藉由倒裝晶片方式連接半導體晶片與電路時, 將形成在半導體晶片的連接用墊上的金、焊錫、鉛、銅、 錫、銀突塊;及此等之合金、金屬與樹脂混合的導電性糊 漿、向異導電性薄膜、在無機物或有機物的球塗敷金屬的 突塊等突塊,直接連接到設在電路上的連接用墊。 〈配線板E &gt; 本發明又可提供,具備有:樹脂層;樹脂層的至少一 個面上的電路;從電路至樹脂層的相反面,突出在樹脂層 中的複數個柱狀的外部連接端子,電路及外部連接端子之 與樹脂層接觸的層,是與樹脂層的密接性很好的金屬層的 配線板E。此配線板E不在電路之與樹脂層接觸的面施加 粗化處理,而是在電路配設與樹脂層的密接性良好的金屬 層。 此配線板E可以,例如,依照本發明的方法,在具有 薄片部及從薄片部的一面突出的複數個柱狀的外部連接端 子的金屬薄片,其具有外部連接端子的表面上,形成外部 連接端子露出前端狀埋沒在絕緣樹脂中的樹脂層,接著, 去除一部分金屬薄片的薄片部直到樹脂層露出,藉此在樹 脂層上形成與外部連接端子連接的電路,而製成。但是, -43- (39) (39)200402812 金屬薄膜是使用,薄片部的突出外部端子的面是與樹脂層 的密接性很好的金屬表面。 本方法所使用的金屬薄片可以使用,例如,依序具有 第1金屬層、與樹脂層的密接性很好的第2金屬層及第3 金屬層的至少3層的多層金屬箔製成。亦即,去除此多層 金屬箔的第1金屬層的一部分,直到露出第2層的金屬層 ’而在第2金屬層的露出面形成複數個柱狀外部連接端子 ,藉此製成上述金屬薄片。多層金屬箔是使用,第1金屬 層、第2金屬層及第3金屬層是鄰接層的蝕刻條件互異的 層時,第1金屬層之部分去除是藉由蝕刻去除,電路之形 成是藉由依序蝕刻去除第2金屬層及第2金屬層的一分性 而形成。 而,上述金屬薄片也可以使用,具有金屬層的第1層 (1);在第1層的一面上的複數個金屬柱(2);及包含與樹 脂層的密接性很好的金屬層,形成在第1層的另一面上的 一層以上的金屬層(3)的複合金屬層製成。亦即,去除此 複合金飾箔的至少一層金屬層,從第1層依次去除金屬柱 下以外的部分,直到露出與樹脂層的密接性很好的金屬層 ,藉此製作金屬薄片。例如,複合金飾箔是依序具有第1 金屬層、與樹脂層的密接性很好的第2金屬層及第3金屬 層的至少3層的多層金屬箔時,可以去除此多層金屬箔的 第1金屬層的一部分,直到露出第2層的金屬層,而在第 2金屬層的露出面形成複數個金屬柱,接著,去除第2金 屬層的金屬柱下部分以外的一部分,直到露出第3金屬層 -44- (40) 200402812 ,藉此製成上述金屬薄片。第1金屬層、第2金屬層及第 3金屬層是鄰接層的蝕刻條件互異的層,第1金屬層及第 2金屬層的部分去除是藉由 蝕刻去除第3金屬層的一部 〈半導體封裝E &gt; 將上述配線板E使用作 獲得,具備有:此配線板E 片;及用以密封配線板E的 的本發明的半導體封裝E。 如,使用不做粗化處理的本 與上述半導體封裝體D的製 在鄰接層是蝕刻條件互 屬可以使用從銅、銅合金、 2金屬在例如第1金屬是銅 合金、欽、鉻、錫、鋅、金 ,可以使用鈦、鉻、錫等。 屬層時,例如,第2金屬是 、金等時,第3金屬可以使 、鉻、錫等時,可以使用鐵 相同的金屬是指,對一種倉虫 的金屬,或各具有對不同蝕 容易粗化的金屬層一般 ,但同樣是銅金屬,化學粗 触刻去除,電路之形成是藉由 分,而形成。 爲半導體封裝用基板,便可以 ;搭載於配線板E的半導體晶 半導體晶片搭載面的密封材料 本發明的半導體封裝E是,例 發明的配線板以外,可以藉由 造方法相同的方法製作。 異的層的多層金屬箔,第1金 鐵、鎳合金等中所選擇者。第 或銅合金時,可以使用鎳、鎳 等,第1金屬是鐵或鎳合金時 多層金屬箔具有3層以上的金 鎳、鎳合金、鈦、鉻、錫、鋅 用銅或銅合金,第2金屬是鈦 、鎳合金等。所謂蝕刻條件不 刻液,有浸蝕性高的金屬與低 刻液的不同浸蝕性的金屬。 是配線板使用的銅、銅合金等 化時,因粒子的差異,電解銅 -45 - (41) 200402812 的粗化較滾軋銅容易。Fig. 13 shows an embodiment of a method for manufacturing a semiconductor package 0 of the present invention. A metal sheet having a sheet portion W and a plurality of external connection terminals X protruding from one side of the sheet portion W is prepared, and the surface of the metal sheet having the external connection terminals X is roughened (No. 13 (a)). Next, the roughened surface of the roughened metal foil was coated with resin 205 to embed the external connection terminal X (Fig. 13 (b)). The resin 2 05 ′ coated on the metal foil is honed until the front end of the external connection terminal X is exposed to form a resin layer z (FIG. 13 (c)). By removing a part of the sheet portion W on the resin layer Z until the resin layer z is exposed, a circuit 206 connected to the external connection terminal X is formed on the resin layer Z, and a wiring board D of the present invention is obtained (FIG. 13 (d)) . On the surface of the circuit 206 and the exposed end surface of the external connection terminal X, nickel / gold plating 207, nickel / solder plating, copper plating, silver plating, etc. are applied as necessary (Fig. 13 (e)). On the surface of the wiring board D having the circuit 206, a wafer bonding film 208 is pasted, and then a semiconductor wafer 20 9 is pasted (Fig. 13 (f)). The semiconductor wafer -42- (38) (38) 200402812 209 is mounted on a wiring board D ( Figure 13 (g)). Next, the semiconductor wafer mounting surface of the wiring board D is sealed with a sealing material 211, and a solder ball 212 is bonded to the exposed surface of the external connection terminal X to obtain a semiconductor package D (FIG. 13 (h)). Furthermore, when a semiconductor wafer and a circuit are connected by a flip-chip method, gold, solder, lead, copper, tin, and silver bumps formed on the connection pads of the semiconductor wafer; and these alloys, metals, and resins are mixed The conductive paste, an anisotropic conductive film, and a bump coated with a metal ball on an inorganic or organic ball are directly connected to a connection pad provided on the circuit. <Wiring board E &gt; The present invention can further provide: a resin layer; a circuit on at least one side of the resin layer; a plurality of columnar external connections protruding from the resin layer from the circuit to the opposite side of the resin layer; The terminals, circuits, and external connection terminals are in contact with the resin layer, and are metal wiring boards E with excellent adhesion to the resin layer. This wiring board E is not provided with a roughening treatment on the surface of the circuit that is in contact with the resin layer, but is provided with a metal layer having good adhesion to the resin layer on the circuit. This wiring board E can, for example, according to the method of the present invention, form an external connection on a metal sheet having a sheet portion and a plurality of columnar external connection terminals protruding from one side of the sheet portion, on the surface having the external connection terminals. The terminal is exposed by a resin layer buried in the insulating resin at the front end shape. Then, a part of the metal foil is removed until the resin layer is exposed, thereby forming a circuit connected to the external connection terminal on the resin layer, and is manufactured. However, -43- (39) (39) 200402812 is a metal thin film, and the surface of the thin portion protruding from the external terminal is a metal surface with good adhesion to the resin layer. The metal sheet used in this method can be made of, for example, a multilayer metal foil having at least three layers of a first metal layer, a second metal layer, and a third metal layer that have good adhesion to the resin layer in this order. That is, a part of the first metal layer of the multilayer metal foil is removed until the second metal layer is exposed, and a plurality of columnar external connection terminals are formed on the exposed surface of the second metal layer, thereby forming the above-mentioned metal sheet. . Multi-layer metal foil is used. When the first metal layer, the second metal layer, and the third metal layer are layers with mutually different etching conditions, the first metal layer is partially removed by etching, and the circuit is formed by The second metal layer and the second metal layer are removed by sequential etching to form the second metal layer. In addition, the above-mentioned metal flakes can also be used, a first layer (1) having a metal layer; a plurality of metal pillars (2) on one side of the first layer; and a metal layer including a good adhesion to the resin layer, A composite metal layer having one or more metal layers (3) formed on the other side of the first layer. That is, at least one metal layer of the composite gold foil is removed, and portions other than the metal pillar are sequentially removed from the first layer until a metal layer with good adhesion to the resin layer is exposed, thereby manufacturing a metal sheet. For example, when the composite gold foil is a multilayer metal foil having at least three layers of a first metal layer, a second metal layer, and a third metal layer in good order in order, the multilayer metal foil can be removed. A part of the first metal layer is formed until the second metal layer is exposed, and a plurality of metal pillars are formed on the exposed surface of the second metal layer. Then, a part other than the lower part of the metal pillar of the second metal layer is removed until the first metal layer is exposed. 3 metal layer -44- (40) 200402812, thereby forming the above-mentioned metal sheet. The first metal layer, the second metal layer, and the third metal layer are layers having mutually different etching conditions. Part of the first metal layer and the second metal layer is removed by removing part of the third metal layer by etching. Semiconductor package E &gt; The above-mentioned wiring board E is used, and is provided with: this wiring board E sheet; and the semiconductor package E of the present invention for sealing the wiring board E. For example, the substrate and the above-mentioned semiconductor package D, which are not subjected to roughening treatment, are used in the adjacent layer under the etching conditions. The copper, copper alloy, and two metals can be used. For example, the first metal is copper alloy, copper, chromium, tin. , Zinc, gold, titanium, chromium, tin, etc. can be used. For the metal layer, for example, when the second metal is gold, etc., when the third metal can be chromium, tin, etc., the same metal can be used, which means that it is easy to corrode one kind of metal or each has different resistance to corrosion. The roughened metal layer is generally, but it is also copper metal, which is removed by chemical rough contact etching, and the circuit is formed by dividing. A semiconductor package substrate may be used; a semiconductor crystal mounted on a wiring board E. A sealing material for a semiconductor wafer mounting surface. The semiconductor package E of the present invention is, for example, a wiring board other than the invention, and can be manufactured by the same method. A multilayer metal foil of a different layer is selected from the first metal, iron, and nickel alloy. In the case of the first or copper alloy, nickel, nickel, etc. can be used. When the first metal is iron or the nickel alloy, the multilayer metal foil has three or more layers of gold-nickel, nickel alloy, titanium, chromium, tin, zinc, or copper or copper alloy. 2 metal is titanium, nickel alloy, and the like. The etching conditions are not etching liquids, and there are metals with high etching properties and metals with different etching properties with low etching liquids. In the case of copper and copper alloys used in wiring boards, the coarsening of electrolytic copper -45-(41) 200402812 is easier than rolling copper due to the difference in particles.

具有第1金屬層、第2金屬層及第3金屬層的至少3 層的多層金屬箔時,形成金屬柱或柱狀的外部連接端子的 第1金屬的厚度最好是12〜100 μηι,超過100 μπι時,形 成金屬柱或外部連接端子的蝕刻準確度低,要形成細緻的 圖案可能很困難,而不足1 2 μιη時,則有可能使金屬柱或 外部連接端子的強度不充分,或絕緣樹脂的絕緣性降低。 更好是18〜70 μπι。第2金屬的厚度最好是0.05〜50 μιη ,超過5 0 μιη時,形成電路時的蝕刻準確度低,要形成細 緻的圖案可能很困難,而不足0.0 5 μιη時,蝕刻第1金屬 時,因爲第2金屬層產生的凹坑或缺口,第3金屬層有被 浸蝕的可能。更好是0.1〜3 5 μιη。第3金屬的厚度最好 是1〜50 μπι,超過50 μιη時,形成電路時的蝕刻準確度 低,要形成細緻的圖案可能很困難,而不足1 μιη時,蝕 刻第1金屬時,因爲第2金屬層產生的凹坑或缺口,第3 金屬層有被浸蝕的可能。更好是5〜1 2 μιη。 ' 形成樹脂層時所使用的樹脂,可以使用絕樹脂材料, 例如:熱硬化性的環氧樹脂、聚醯亞胺樹脂、矽樹脂、聚 醯胺醯亞胺樹脂、聚苯撐硫醚樹脂、感光性聚醯亞胺樹脂 、丙烯環氧樹脂、乙烯、丙烯、苯乙烯、丁二烯等熱可塑 性彈性體,液晶聚合物等。樹脂層的厚度,通常是跟鈾刻 第1金屬層或第1金屬層及第2金屬層形成的外部連接端 子的高度相同。 相互間的密接性良好的金屬層與樹脂層的組合有,例 -46 - (42) (42)200402812 如:矽變性聚醯亞胺樹脂的矽量多時,與銅金屬層的密接 性良好,而矽量少時,與鎳金屬層的密接性良好。 外部連接端子的形狀的形狀是實心的金屬柱,沒有特 別限制,通常是半徑1 0〜7 5 0 μηι的圓柱,短側的一邊的 寬度20 μιη以上的方形等。 本發明的基板C及Ε可以是僅具有一層絕緣樹脂層 者,也可以是具有絕緣樹脂層的下面再經由絕緣層堆疊的 複數個導體電路層的多層配線板。 本發明的基板C及Ε可以當作半導體封裝所用的插 入基板的半導體封裝用基板,或當作搭載半導體封裝的電 子零件的母板等配線板,在製造各種半導體裝置時使用。 半導體封裝的密封可以藉由,使用絕緣樹脂的塑模、 轉換塑模、罐燒、澆鑄,使用遮蔽印刷法的樹脂封裝等實 施。樹脂密封所使用的絕緣樹脂沒有特別限定,可以使用 :例如,環氧樹脂、矽樹脂、酚樹脂、環氧變性酚樹脂等 〇 以下擬再參照本發明的實施例及其比較例,進一步具 體說明本發明,但本發明並非限定在此等實施例。 實施例1〜9 實施例1 (半導體封裝用基板Α) 參照附圖說明本發明的一實施例。第1圖是表示在具 有導電性突起的金屬箔形成多層樹脂層的各製程的截面圖 。第1圖(a)表示形成跟具有導電性突起a的金屬箔7的 -47- (43) 200402812When the multilayer metal foil has at least three layers of the first metal layer, the second metal layer, and the third metal layer, the thickness of the first metal forming the metal pillar or the column-shaped external connection terminal is preferably 12 to 100 μηι, which exceeds At 100 μm, the accuracy of etching for forming metal pillars or external connection terminals is low, and it may be difficult to form a detailed pattern. When less than 12 μm, the strength of the metal pillars or external connection terminals may be insufficient, or the insulation may be insufficient. The insulation of the resin is reduced. It is more preferably 18 to 70 μm. The thickness of the second metal is preferably 0.05 to 50 μιη. When it exceeds 50 μιη, the accuracy of etching when forming a circuit is low, and it may be difficult to form a detailed pattern. When it is less than 0.0 5 μιη, when etching the first metal, The third metal layer may be etched due to the pits or notches generated by the second metal layer. More preferably, it is 0.1 to 3 5 μm. The thickness of the third metal is preferably 1 to 50 μm. When it exceeds 50 μm, the accuracy of etching when forming a circuit is low, and it may be difficult to form a detailed pattern. When it is less than 1 μm, when etching the first metal, The pits or notches generated by the 2 metal layer, and the third metal layer may be etched. More preferably, it is 5 to 12 μm. '' The resin used when forming the resin layer can be made of insulating materials, such as thermosetting epoxy resin, polyimide resin, silicone resin, polyimide resin, polyphenylene sulfide resin, Photosensitive polyfluorene imide resins, propylene epoxy resins, thermoplastic elastomers such as ethylene, propylene, styrene, butadiene, and liquid crystal polymers. The thickness of the resin layer is usually the same as the height of the external connection terminals formed by the first metal layer or the first metal layer and the second metal layer. The combination of the metal layer and the resin layer with good adhesion to each other includes, for example, -46-(42) (42) 200402812. For example, when the silicon content of the silicon-modified polyimide resin is large, the adhesion to the copper metal layer is good. When the amount of silicon is small, the adhesion with the nickel metal layer is good. The shape of the external connection terminal is a solid metal column, which is not particularly limited. Usually, the shape of the external connection terminal is a cylinder with a radius of 10 to 75 μm, and a square with a width of 20 μm or more on the short side. The substrates C and E of the present invention may be a multilayer wiring board having only one insulating resin layer, or a plurality of conductor circuit layers stacked under the insulating resin layer and then stacked through the insulating layer. The substrates C and E of the present invention can be used as a semiconductor package substrate for an interposer substrate for a semiconductor package, or as a wiring board such as a mother board on which electronic components of the semiconductor package are mounted, and are used when manufacturing various semiconductor devices. The sealing of the semiconductor package can be performed by using a mold of an insulating resin, a conversion mold, canning, casting, or a resin package using a mask printing method. The insulating resin used for the resin sealing is not particularly limited, and can be used, for example, epoxy resin, silicone resin, phenol resin, epoxy-modified phenol resin, etc. The following is a detailed description with reference to the embodiments and comparative examples of the present invention. The invention, but the invention is not limited to these examples. Embodiments 1 to 9 Embodiment 1 (Semiconductor Package Substrate A) An embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view showing each process of forming a multilayer resin layer on a metal foil having conductive protrusions. Fig. 1 (a) shows the formation of a metal foil 7 with a conductive protrusion a -47- (43) 200402812

接合性良好的第1樹脂層1的製程。在此,具有導電性突 起A的金屬箔7是以下述方式製成。使用7才卜K歹彳 7彳;1/厶 Η - K350(日立化成工業(株)製)在厚度7〇 μπι的銅層、〇·2 μηι的鎳層、1〇 μιη的銅層構成的3層金 屬箔(日本電解(株))形成圖案,再使用&gt; Α 7 7夕只社製 工一 口七7液(含氨銅醋鹽20〜30重量%、氯化氨10〜 2 0重量%及氨1〜1 〇重量%)構成的鹼性蝕刻液選擇性鈾 刻70 μηι銅層,在露出的鎳層表面形成由銅構成的金屬柱 。這時,使金屬柱成爲Φ2 5 0 μηι的圓柱。接著,使用由硝 酸·過氧化氫水溶液構成的蝕刻液選擇性去除鎳層的金屬 柱下以外的部分,藉此形成由銅及鎳構成的φ 2 5 0 μ m的圓 柱狀導電性突起A。爲了使其樹脂有良好的密接性,在露 出的10 μιη的銅層表面施加化學磷系處理。Process for manufacturing the first resin layer 1 with good adhesion. Here, the metal foil 7 having the conductive protrusion A is made in the following manner. 77K 歹 彳 7 彳; 1 / K-K350 (manufactured by Hitachi Chemical Industries, Ltd.) is composed of a copper layer with a thickness of 70 μm, a nickel layer with a thickness of 0.2 μm, and a copper layer with a thickness of 10 μm. Three layers of metal foil (Nippon Electrolytic Co., Ltd.) are patterned and reused.> Α 7 7 Yuka Co., Ltd. a mouthful of 7 7 liquid (containing ammonia copper salt 20-30% by weight, ammonia chloride 10 ~ 20 weight % And ammonia (1 to 10% by weight) are used to selectively etch a 70 μm copper layer using an alkaline etching solution consisting of copper, and form a metal pillar made of copper on the surface of the exposed nickel layer. At this time, the metal pillar was made into a cylinder of Φ2 50 μm. Next, an etching solution made of an aqueous solution of nitric acid and hydrogen peroxide was used to selectively remove portions other than under the metal pillars of the nickel layer, thereby forming a cylindrical conductive protrusion A of φ 2 50 μm made of copper and nickel. In order to make the resin have good adhesion, a chemical phosphorus treatment was applied to the surface of the exposed 10 μm copper layer.

形成第1樹脂層1時使用由矽變性聚醯胺亞胺樹脂構 成的KS 6 6 00 (日立化成工業(株)製)。以印刷機VE - 500 (東7工$二7 U &gt; / (株)製)印刷流動狀淸漆狀態的 黏度40 Pa · s的上述樹脂。1 8表示掩罩,1 7表示擠壓機 。印刷後,以8 0 °C乾燥3 0分鐘,形成沒有流動性的半硬 化狀態的第1樹脂層1。乾燥後的第1樹脂層1的厚度( 水平部分之厚度:以下同)是20 μηι。 其次,使用在KS 6600含有75 %無機粒子(二氧化矽) 的樹脂,以流動狀淸漆狀態印刷在第1樹脂層1上。與第 1樹脂層1相同,以8 0 °C乾燥3 0分鐘,形成沒有流動性 的半硬化狀態的第2樹脂層2(第1圖(b))。乾燥後的第2 -48- (44) (44)200402812 樹脂層2的厚度是30 μιη。 如第1圖(c)所示’在第2樹脂層2上印刷流動狀淸 漆狀態的KS 6600。塗抹後以80°C乾燥30分鐘,使成沒 有流動性的半硬化狀態,而形成第3樹脂層3。乾燥後的 第3樹脂層3的厚度是25 μιη。 在金屬箔7形成由第1樹脂層1、第2樹脂層2及第 3樹脂層3構成的3層半硬化狀態的樹脂後,如第1圖(d) 所示,爲了使埋沒的導電性突起A的端面露出絕緣性樹 脂表面,以絕緣性樹脂層成半硬化的狀態下,用市售的硏 磨紙加以硏磨。硏磨時間是,2 5 0 mm X 250 mm的金屬箔 上的絕緣樹脂層表面可以用# 4 0 0硏磨紙硏磨3 0分鐘/ 枚。作爲比較例子的硏磨完全硬化狀態的絕緣樹脂層時, 是用相同硏磨紙硏磨60分鐘/枚。 .如第1圖(e)所示,硏磨後,以1 8 0 °C加熱3 0分鐘、 以220 °C加熱10分鐘,使在半硬化狀態的3層的樹脂層 完全硬化,而成硬化樹脂層4、5、6。 形成硬化樹脂層後的半導體封裝用的本構件,在令樹 脂完全硬化後也沒有翹曲或波浪,十分平坦。並使用所獲 得的構件,以&gt; A7 V夕只社製工一 7° 口七只液蝕刻金 屬箔表面(與導電性突起相反的面),形成電路。然後,在 電路表面及導電性突起的露出面施加電解鎳/金電鍍,製 成半導體封裝用基板。所獲得的半導體封裝用基板也同樣 平坦。而樹脂層與銅的脫皮強度是1.2 Kg/cm,較以高比 率(60重量%)調配無機粒子的樹脂層與銅的脫皮強度0.5 (45) 200402812 K g / c m 強。 實施例2(內設元件型半導體封裝用基板) 第2圖表示本實施例的製程的截面圖。以下’按照製 程順序進行說明。For the formation of the first resin layer 1, KS 6 6 00 (manufactured by Hitachi Chemical Co., Ltd.) made of a silicon-denatured polyimide resin was used. The above resin with a viscosity of 40 Pa · s in the state of flowing varnish was printed on a printing press VE-500 (manufactured by Toshiko Koji $ 27 U &gt; / Co., Ltd.). 1 8 means mask, 1 7 means extruder. After printing, it was dried at 80 ° C for 30 minutes to form a first resin layer 1 in a semi-hardened state having no fluidity. The thickness of the first resin layer 1 after drying (the thickness of the horizontal portion: the same applies hereinafter) is 20 μm. Next, a resin containing 75% of inorganic particles (silicon dioxide) in KS 6600 was used to print on the first resin layer 1 in a flowing varnished state. Similar to the first resin layer 1, it was dried at 80 ° C for 30 minutes to form a second resin layer 2 in a semi-hardened state without fluidity (Fig. 1 (b)). After drying, the thickness of 2 -48- (44) (44) 200402812 resin layer 2 was 30 μm. As shown in Fig. 1 (c), 'KS 6600 is printed on the second resin layer 2 in a flowing state. After the application, it was dried at 80 ° C for 30 minutes to form a semi-hardened state with no fluidity, and a third resin layer 3 was formed. The thickness of the third resin layer 3 after drying was 25 μm. After the metal foil 7 is formed into three layers of semi-hardened resin composed of the first resin layer 1, the second resin layer 2, and the third resin layer 3, as shown in FIG. 1 (d), in order to make buried conductivity The end surface of the protrusion A is exposed to the surface of the insulating resin, and the insulating resin layer is semi-hardened, and is then honed with a commercially available honing paper. The honing time is that the surface of the insulating resin layer on a 250 mm X 250 mm metal foil can be honed with # 4 0 0 honing paper for 30 minutes per piece. As a comparative example, the insulating resin layer in the fully hardened state was honed with the same honing paper for 60 minutes / piece. As shown in Figure 1 (e), after honing, heating at 180 ° C for 30 minutes, and 220 ° C for 10 minutes, the three resin layers in the semi-hardened state are completely hardened. Hardened resin layers 4, 5, 6. This member for a semiconductor package after the hardened resin layer is formed is very flat without warping or wavy even after the resin is completely hardened. And using the obtained member, the surface of the metal foil (the surface opposite to the conductive protrusion) was etched with a 7 ° mouth seven liquids using &gt; A7 V. Co., Ltd. to form a circuit. Then, electrolytic nickel / gold plating was applied to the circuit surface and the exposed surface of the conductive protrusions to prepare a substrate for a semiconductor package. The obtained semiconductor package substrate was also flat. The peeling strength of the resin layer and copper is 1.2 Kg / cm, which is stronger than the peeling strength of the resin layer formulated with inorganic particles and copper at a high ratio (60% by weight) of 0.5 (45) 200402812 K g / cm. Example 2 (Substrate for Semiconductor Device with Built-in Type) FIG. 2 is a cross-sectional view showing a manufacturing process of this example. The following 'is explained in the order of processes.

第2圖(a)的具有導電性突起A的金屬范7是以下述 方式製成。使用7才卜卜、歹〆厶H — K35〇(臼立化 成工業(株)製)在厚度100 Mm的銅層、〇·2 的鎳層、5 μιη的銅層構成的3層金屬箔(日本電解(株))形成圖案,再 使用 &gt; 少亍7 7夕只社製工一7。口七只液(含氨銅醋鹽2〇 〜30重量%、氯化氨1〇〜20重量%及熱1〜1〇重量%) 構成的鹼性蝕刻液選擇性蝕刻1 〇〇 銅層,在露出的鎳The metal sample 7 having the conductive protrusion A of Fig. 2 (a) is made in the following manner. Three layers of metal foil (7 layers) made of 才 H-K35〇 (manufactured by Usili Chemical Co., Ltd.) with a copper layer of 100 Mm thickness, a nickel layer of 0.2, and a copper layer of 5 μm Japan Electrolysis Co., Ltd.) forms a pattern and reuses it. Alkaline etching solution consisting of seven liquids (containing 20-30% by weight of copper copper vinegar salt, 10-20% by weight of ammonia chloride, and 1-10% by weight of heat) selectively etches the 1,000 copper layer, Exposed nickel

層表面形成由銅構成的金屬柱。這時’使金屬柱成爲Φ 2 5 0 μηι的圓柱。接著,使用由硝酸•過氧化氫水溶液構成的 蝕刻液選擇性去除鎳層的金屬柱下以外的部分’藉此形成 由銅及鎳構成的Φ2 5 0 μπι的圓柱狀導電性突起Α。爲了使 其樹脂有良好的密接性,在露出的5 μπι的銅層表面施加 化學磷系處理。 在所準備的具有導電性突起的金屬箔7,使用晶片焊 接用糊漿ΕΝ - Χ50Ν(日立化成工業(株)製)19,固定尺寸 6·5 X 6.5 mm、厚度0.05 0 mm的半導體晶片1〇,並使其 A1電極B接觸在未形成導電性突起A的銅箔面。這時, 避免晶片焊接用糊漿附著在半導體晶片的連接墊部。 第2圖(b)與實施例1同樣,是使用由矽變性聚醯胺 -50- (46) (46)200402812 亞胺樹脂構成的KS6600 (日立化成工業(株)製)及由此樹 脂與無機粒子形成的樹脂,形成由半硬化狀態的第1樹脂 層1、第2樹脂層2及第3樹脂層3構成的3層絕緣樹脂 層後,以樹脂成半硬化的狀態下進行硏磨,使埋沒的導電 性突起A的端面露出後,使3層的樹脂完全硬化時的截 面圖。再者,乾燥後的各樹脂層厚度是,第1樹脂層1的 厚度爲30 μιη、第2樹脂層2爲40 μπι、第3樹脂層3爲 3 5 μηι。 第2圖(c)是選擇性蝕刻厚度5 μ m的銅層形成電路C 的截面圖。這時,對搭載半導體晶片1 〇部分的銅箔加以 蝕刻,使其僅露出晶片的連接墊部分。 第2圖(d)所示者是,爲了連接露出的半導體晶片的 A1電極B與形成的電路C,在A1電極B部分塡孔印刷導 電性糊漿的卜'' 一 T &gt;卜(二木&gt;/、&gt;〆(株)製)2 0,然後, 以1 8 (TC,硬化3 0分鐘的截面圖。 第2圖(e)是,準備,藉由跟實施例1相同的製程在 具有導電性突起的金屬箔形成3層的半硬化狀態的絕緣樹 脂層的構件。 第2圖(f)是藉由真空壓製裝置,在真空下將第2圖 (e)所準備的構件,加熱壓接成第2圖(d)所示的構件的截 面圖。藉由加熱,半硬化狀態的第2圖(c)的構件的樹脂 先軟化,再加壓將樹脂擠入電路間,接合於第2圖(d)的 構件。層間的接合是藉由埋設的銅構成的導電性突起A, 與由5 μτη的銅層形成的電路C之間爲之。 -51 - (47) (47)200402812 第2圖(f)時,是層間的連接藉由周圍的樹脂的接合 力使導電性突起A與電路C相接觸的狀態,爲了提高連 接可靠性,可以考慮:在導電性突起A的露出部與電路c 施加鍍金,以提高密接性;在同樣處所施加焊錫電鍍,在 壓接連接時或壓接後加熱到焊錫熔融溫度以上,藉由焊接 連接;或在壓接前在導電性突起A的露出部或電路C的 連接部或在雙方部位塗抹導電性接合劑,在壓接時,同時 接合硬化的方法。 第2圖(g)是使加熱壓接的構件的第1樹脂層1、第2 樹脂層2、及第3樹脂層3所形成的絕緣樹脂層完全硬化 ,成爲由硬化樹脂層4、硬化樹脂層5及硬化樹脂層6所 構成的層後的截面圖。 硬化後,進行電解鎳/金電鍍(大和電機工業(株)製) ,製成具有第2圖(g)所示截面構造的內設半導體晶片的 半導體封裝用基板。 實施例3 (內設元件型的三維半導體封裝) 第3圖表示進行本實施例的製程的截面圖。製成以玻 璃環氧基材1 4作爲絕緣層的兩面配線板當作基礎基板(第 3圖(a))。在此兩面基板的配線8上搭載端子部備有金突 塊9的LSI元件10 (厚度50 μηι),再藉熱壓接,將金突 塊9與配線8相互連接(第3圖(b))。將如此製成的裝配體 ,與實施例1同樣,使用由矽變性聚醯胺亞胺樹脂構成的 KS6600 (日立化成工業(株)製)及由此樹脂與無機粒子形 (48) (48)200402812 成的樹脂,形成由半硬化狀態的第1樹脂層1、第2樹脂 層2及第3樹脂層3構成的3層絕緣樹脂層(第3圖(c))。 再者’乾燥後的各樹脂層的抗蝕劑1 2上的厚度是,第1 樹脂層1的厚度爲40 μηι、第2樹脂層2爲60 μηι、第3 樹脂層3爲4 0 μηι。半硬化後進行硏磨,接著使絕緣樹脂 層的樹脂完全硬化。 形成硏磨而完全硬化表面平坦的絕緣樹脂層後,鑽設 層間連接用的通孔,藉由使用無電解鍍銅的添加法形成多 層配線,在其上面形成抗蝕劑1 2而形成配線圖案11 (第3 圖(d))。然後,在形成的配線圖案1 1上搭載備有金突塊9 的L SI元件丨0,藉熱壓接將金突塊9與配線圖案1 1相互 連接’在L S I元件1 0與抗蝕劑1 2間塡充液狀環氧樹脂( 塡底材)1 3令其硬化,獲得內設元件型的三維半導體封裝( 弟3圖(e ))。 實施例4(半導體封裝用基板C、半導體裝置C) 以下述方法製成具有第4圖所示截面的〇 · 5 m m間距 半導體封裝用基板C。使用7才卜K ^ 4 4少厶Η - Κ350(日立化成工業(株)製)在厚度7〇 銅層、〇·2 μτη 的鎳層、1 〇 μ m的銅層構成的3層金屬箱(日本電解(株)製 )的7 〇 μηι的銅層形成圖案,再使用 &gt; 少亍V 7夕只社製 工一 7° 口七只液(含氨銅醋鹽20〜30重量%、氯化氨 〜2 0重量%及氨1〜1 〇重量%)構成的鹼性蝕刻液選擇性 蝕刻銅,形成20個φ2 5 0 μιη的銅突塊。再留下銅突塊的 -53- (49) 200402812A metal pillar made of copper is formed on the surface of the layer. At this time ', the metal pillar is made into a cylinder of Φ 2 50 μm. Next, an etching solution made of an aqueous solution of nitric acid and hydrogen peroxide was used to selectively remove portions other than under the metal pillars of the nickel layer ', thereby forming a cylindrical conductive protrusion Φ2 50 μm made of copper and nickel. In order to make the resin have good adhesion, a chemical phosphorus-based treatment was applied to the surface of the exposed 5 μm copper layer. On the prepared metal foil 7 having conductive protrusions, a semiconductor wafer 1 having a size of 6.5 X 6.5 mm and a thickness of 0.05 0 mm was fixed by using a wafer solder paste EN-X50N (manufactured by Hitachi Chemical Industries, Ltd.) 19. 〇, and the A1 electrode B was brought into contact with the copper foil surface on which the conductive protrusion A was not formed. At this time, the soldering paste is prevented from adhering to the connection pad portion of the semiconductor wafer. Fig. 2 (b) is the same as in Example 1, using KS6600 (manufactured by Hitachi Chemical Co., Ltd.) composed of silicon modified polyamido-50-50 (46) (46) 200402812 imine resin, and the resin and The resin formed by the inorganic particles is formed into a three-layer insulating resin layer composed of a first resin layer 1, a second resin layer 2 and a third resin layer 3 in a semi-hardened state, and then is honed with the resin in a semi-hardened state. A cross-sectional view when the three-layer resin is completely cured after the end surfaces of the buried conductive protrusions A are exposed. The thickness of each resin layer after drying was 30 μm for the first resin layer 1, 40 μm for the second resin layer 2, and 3 5 μm for the third resin layer 3. Fig. 2 (c) is a cross-sectional view of a circuit C formed by selective etching of a copper layer having a thickness of 5 µm. At this time, the copper foil on which the semiconductor wafer 10 portion is mounted is etched so that only the connection pad portion of the wafer is exposed. As shown in FIG. 2 (d), in order to connect the exposed semiconductor wafer A1 electrode B and the formed circuit C, a conductive paste is printed on the A1 electrode B part. A T &gt; A (2) Wood &gt; /, &gt; manufactured by Hori Co., Ltd. 20, and then cross-sectional view at 18 (TC, hardened for 30 minutes. Fig. 2 (e) is prepared by the same method as in Example 1 In the manufacturing process, three layers of a semi-hardened insulating resin layer are formed on a metal foil having conductive protrusions. Fig. 2 (f) shows a member prepared in Fig. 2 (e) under vacuum by a vacuum pressing device. , Heat-pressed to form a cross-sectional view of the member shown in Figure 2 (d). By heating, the resin in the member of Figure 2 (c) in a semi-hardened state is first softened, and then pressed to squeeze the resin into the circuit room, Bonded to the member in Figure 2 (d). Interlayer bonding is made between conductive protrusion A made of buried copper and circuit C made of a copper layer of 5 μτη. -51-(47) ( 47) 200402812 In Fig. 2 (f), the connection between the layers is in a state where the conductive protrusion A is in contact with the circuit C by the bonding force of the surrounding resin. In order to improve the connection Reliability can be considered: gold plating is applied to the exposed portion of the conductive protrusion A and the circuit c to improve the adhesion; solder plating is applied to the same place, and it is heated above the melting temperature of the solder during or after the crimp connection. Solder connection; or a method of applying a conductive adhesive to the exposed portion of conductive protrusion A, the connection portion of circuit C, or both parts before crimping, and simultaneously bonding and hardening during crimping. Figure 2 (g) is The insulating resin layer formed by the first resin layer 1, the second resin layer 2, and the third resin layer 3 of the member which is thermocompression-bonded is completely hardened, and becomes a hardened resin layer 4, a hardened resin layer 5, and a hardened resin layer 6. Cross-section view of the formed layer. After hardening, electrolytic nickel / gold plating (manufactured by Yamato Denki Kogyo Co., Ltd.) is performed to produce a semiconductor package with a built-in semiconductor wafer having a cross-sectional structure shown in FIG. 2 (g) Example 3. (Three-dimensional semiconductor package of built-in type) FIG. 3 is a cross-sectional view showing a process of performing this example. A two-sided wiring board with a glass epoxy substrate 14 as an insulating layer was used as a base substrate. (Section 3 (a)). The LSI element 10 (thickness: 50 μηι) with gold bumps 9 on the terminals 8 is mounted on the wiring 8 on this two-sided substrate, and then the gold bumps 9 and the wiring 8 are connected by thermocompression bonding. (Figure 3 (b)). The assembly thus prepared was used in the same manner as in Example 1 using KS6600 (manufactured by Hitachi Chemical Co., Ltd.) composed of a silicon-denatured polyamidoimine resin, and the resin and Inorganic particle shape resin (48) (48) 200402812, a three-layer insulating resin layer consisting of a first resin layer 1, a second resin layer 2 and a third resin layer 3 in a semi-hardened state (Fig. 3 (c )). Furthermore, the thickness of the resist 12 on each resin layer after drying is that the thickness of the first resin layer 1 is 40 μm, the thickness of the second resin layer 2 is 60 μm, and the thickness of the third resin layer 3 is 4 0 μηι. After semi-hardening, honing was performed, and then the resin of the insulating resin layer was completely hardened. After forming a honing and completely hardening insulating resin layer with a flat surface, drill through holes for interlayer connection, form a multilayer wiring by using an electroless copper plating method, and form a resist 12 on the wiring to form a wiring pattern. 11 (Figure 3 (d)). Then, an L SI element with a gold bump 9 is mounted on the formed wiring pattern 11, and the gold bump 9 and the wiring pattern 11 are connected to each other by thermocompression bonding. The LSI element 10 and the resist are connected to each other. 1 2 2 塡 liquid-filled epoxy resin (塡 substrate) 1 3 to harden it to obtain a three-dimensional semiconductor package with built-in components (Figure 3 (e)). Example 4 (Substrate C for Semiconductor Packaging, Semiconductor Device C) A semiconductor package substrate C with a 0.5-m pitch having a cross-section as shown in FIG. 4 was prepared by the following method. A 7-layer metal box consisting of K ^ 4 4 Shao-K350 (manufactured by Hitachi Chemical Industries, Ltd.) with a thickness of 70 copper layers, a nickel layer of 0.2 μτη, and a copper layer of 10 μm (Manufactured by Nippon Electrolytic Co., Ltd.) to form a pattern of a copper layer of 70 μm, and use it again.> Shaoyu V 7 Xijia Co., Ltd. 7 ° mouth seven liquid (containing ammonia copper vinegar salt 20-30% by weight, Alkaline etching solution composed of ammonia chloride (~ 20% by weight and ammonia (1 ~ 10% by weight)) selectively etches copper to form 20 copper bumps of φ2 50 μm. Leaving copper bumps -53- (49) 200402812

直上部選擇性蝕刻去除鎳層,形成由銅層及鎳層形成的金 屬柱1 0 3。鎳層的蝕刻使用&gt; A7 7夕只社製/ A 7卜 U 7 7° N - 95 0 (含硫酸8重量%、硝酸5重量%及過氧化 氫3 .5重量%)的原液形成的蝕刻液。接著,在3層金屬 箔的形成金屬柱1 〇3的面上,爲了使其與樹脂的密接性較 佳,以線速度 1 .75 m/min、噴霧壓力 9 · 8 χ 1 04 P a (1 · 0 kgf/cm2)的條件施加化學磷系處理(使用荏原電產(株)製處 理液,NBD II處理液(硫酸7.5重量%、磷酸3.8重量%、 過氧化氫4.0重量%)的NBD II系統的處理)。在此金飾箔 的形成金屬柱1〇3的面上,以印刷機VE - 5 00 (東k工y 二7 9 y /(株)製)印刷液狀的矽變性聚醯胺亞胺樹脂 的絕緣樹脂 KS 6600(日立化成工業(株)製),埋沒金屬柱 103後,進行以80 °C加熱30分鐘、180 °C加熱30分鐘, 220 °C加熱20分鐘的3階段硬化,用市售的硏磨紙硏磨, 直到埋設的金屬柱1 的端面出現,而形成絕緣樹脂層 1 〇 6。接著,使用 &gt; 少亍7 7夕只社製工一 7° 口七只液(含 氨銅醋鹽20〜30重量°/〇、氯化氨10〜20重量%及氨1〜 1 0重量%)原液構成的鹼性蝕刻液選擇性蝕刻金屬箔的厚 度ΙΟμπι的銅,在金屬柱103上形成φ300 μιη的銅的電路 1 1 1。然後,在電路表面形成電解鎳/金電鍍(Ni/ Au電 鍍109 )(大和電機工業(株)製),製成具有如第4圖所示的 截面構造的〇. 5 mm間距的半導體封裝用基板。在此基板 ,使半導體晶片105與基板的線焊接用連接墊101之200 個全部爲金屬柱103上的電路1 1 1。在金屬柱103的下端 -54 - (50) 200402812The nickel layer is selectively etched away from the straight upper part to form a metal pillar 103 formed of a copper layer and a nickel layer. The nickel layer was etched using a stock solution made of A7 and only A7 and U7 7 ° N-95 0 (containing 8% by weight sulfuric acid, 5% by weight nitric acid, and 3.5% by weight hydrogen peroxide). Etching solution. Next, on the surface on which the metal pillars 103 of the three-layer metal foil were formed, in order to make the adhesiveness with the resin better, the linear velocity was 1.75 m / min and the spray pressure was 9 · 8 χ 1 04 P a ( 1 · 0 kgf / cm2) under application of chemical phosphorus system treatment (using NBD II treatment solution, NBD II treatment solution (7.5% by weight sulfuric acid, 3.8% by weight phosphoric acid, 4.0% by weight hydrogen peroxide) NBD II system). On the surface where the metal pillar 103 of the gold foil is formed, a silicon-modified polyimide resin in the form of a liquid was printed with a printing press VE-5 00 (manufactured by Tokko Y 279 y / Co., Ltd.). Insulating resin KS 6600 (manufactured by Hitachi Chemical Co., Ltd.), after the metal pillar 103 is buried, it is heated at 80 ° C for 30 minutes, 180 ° C for 30 minutes, and 220 ° C for 20 minutes. A commercially available honing paper is honed until the end face of the buried metal pillar 1 appears, and an insulating resin layer 106 is formed. Next, use &gt; Shaoqi 7 Qixi Co., Ltd. 7 ° Mouth of seven liquids (containing ammonia copper vinegar salt 20 ~ 30 weight ° / 〇, ammonia chloride 10 ~ 20 weight% and ammonia 1 ~ 10 weight %) A basic etching solution composed of a raw solution selectively etches copper with a thickness of 10 μm from a metal foil to form a copper circuit with a diameter of 300 μm on a metal pillar 103. Then, an electrolytic nickel / gold plating (Ni / Au plating 109) (manufactured by Yamato Denki Kogyo Co., Ltd.) was formed on the circuit surface, and a semiconductor package for a 0.5 mm pitch having a cross-sectional structure as shown in FIG. 4 was formed. Substrate. In this substrate, all of the 200 connection pads 101 for wire bonding between the semiconductor wafer 105 and the substrate are circuits 1 1 1 on the metal pillar 103. At the lower end of metal pillar 103 -54-(50) 200402812

面,經由Ni/ An電鍍109形成焊錫突塊〗10。第8圖(a) 表示使用此第4圖的基板製造的半導體積體電路裝置的配 線圖案的部分平面圖。在此基板上褡載尺寸8.5 mm X 8.5 mm、厚度0.3 mm的半導體晶片1 〇5,而以金引線丨07連 接,設在屬柱1 0 3直上的電路1 1 1的接用墊1 〇 1,與半導 體晶片105的連接用墊(未圖示)。這時,爲了比較,也準 備’與傳統的半導體封裝用基板同樣,形成從所有2 0 0個 金屬柱1 03的直上方布放的電路,在其前端於絕緣樹脂上 的電路配設連接用墊的基板。第8圖(b)表示使用此基板 製造的半導體裝置的配線圖案的部分平面圖。搭載於基板 上的導體晶片105的連接用墊(未圖示),與從所有的金屬 柱1 03直上方布放的電路1 1 3之設在絕緣樹脂上前端部之 連接用墊1 02焊接。其結果,基板尺寸在傳統的電路設計 是如第8圖所示,成爲15 X 15 mm,但所有200個連接 用墊全部都在金屬柱1 〇 3直上部時,則成爲1 3 X 1 3 mm 。這表示基板縮小25 %。焊接在使用線焊接器HW 2100( 九州松下電器(株)製)蝕刻而形成的金屬柱1 〇3直上部的 處所的焊接不良率是0.009 %,較之形成在藉由電路布放 而形成在絕緣樹脂上的電路的連接用墊的〇.〇3 %少。 實施例5(半導體封裝用基板C、半導體裝置C1) 除了將層間連接用的金屬柱的數目增加到3 8 4個’在 其中的1 6 0個金屬柱直上部的電路設連接用墊,從剩餘的 2 24個金屬柱布放電路,在其前端配設連接用墊以外’使 -55- (51) 200402812 用與實施例一樣的3層金屬箔及液狀樹脂,與實施例4同 樣製成半導體封裝用基板。第9圖(a)表示,將半導體晶 片搭載於此基板’再線焊接,而製作成的半導體積體電路 裝置的配線圖案的部分平面圖。同時,爲了比較,製作藉 由布放電路圖案將全部的連接用墊形成在絕緣樹脂上的電 路上的基板。第6圖(b)表示,將半導體晶片搭載於此比 較用基板,再線焊接,而製作成的半導體積體電路裝置的 配線圖案的部分平面圖。其結果,線焊接在層間連接用的 金屬柱直上部的1 20個半導體封裝用基板的尺寸是,比較 用的基板是1 4 X 1 4 mm,但本實施例可以使基板的尺寸 爲 12 X 12 mm。 實施例6 (配線板D、半導體封裝體D)10, a solder bump is formed via Ni / An plating 109. FIG. 8 (a) is a partial plan view showing a wiring pattern of a semiconductor integrated circuit device manufactured using the substrate of FIG. 4. FIG. A semiconductor wafer 1 0 5 having a size of 8.5 mm X 8.5 mm and a thickness of 0.3 mm is loaded on this substrate, and is connected with gold leads 丨 07, and the circuit pad 1 1 1 provided directly on the metal pillar 1 0 3 1. A pad (not shown) for connection with the semiconductor wafer 105. At this time, for comparison, it is also prepared to form a circuit that is laid directly above all 200 metal pillars 103, as in a conventional semiconductor package substrate, and a connection pad is provided on the front end of the circuit on an insulating resin. Of the substrate. Fig. 8 (b) is a partial plan view of a wiring pattern of a semiconductor device manufactured using this substrate. The connection pads (not shown) of the conductor chip 105 mounted on the substrate are soldered to the connection pads 1 02 of the circuit 1 1 3 provided on the top end of the insulating resin, which are arranged directly above all the metal posts 103. . As a result, the conventional circuit design has a size of 15 X 15 mm as shown in Fig. 8. However, when all the 200 connection pads are located directly above the metal pillar 103, it becomes 1 3 X 1 3 mm. This means that the substrate is reduced by 25%. The welding defect rate of the space directly above the metal pillar 103 formed by etching with a wire welder HW 2100 (made by Kyushu Matsushita Electric Co., Ltd.) is 0.009%, which is lower than that when it is formed by wiring in a circuit. 0.33% of the pad for connecting the circuit on the insulating resin is less. Example 5 (Semiconductor package substrate C, semiconductor device C1) In addition to increasing the number of metal pillars for interlayer connection to 3,84, of which 160 metal pillars are directly above the circuit, connection pads are provided. The remaining 2 24 metal pillars are placed in the circuit, and the front end is provided with a connection pad other than a connection pad. '55-(51) 200402812 The same three-layer metal foil and liquid resin as in Example 4 were used to make the same as in Example 4. A semiconductor package substrate is formed. Fig. 9 (a) shows a partial plan view of a wiring pattern of a semiconductor integrated circuit device produced by mounting a semiconductor wafer on this substrate 'and wire bonding. At the same time, for comparison, a circuit board in which all the connection pads are formed on an insulating resin by laying out a circuit pattern is produced. Fig. 6 (b) shows a partial plan view of a wiring pattern of a semiconductor integrated circuit device fabricated by mounting a semiconductor wafer on this comparison substrate and wire bonding. As a result, the size of 120 substrates for semiconductor packaging, which are wire-bonded to the straight upper part of the metal pillar for interlayer connection, is 1 4 X 1 4 mm for the comparison substrate. However, in this embodiment, the size of the substrate can be 12 X 12 mm. Example 6 (wiring board D, semiconductor package D)

使用7才卜K'歹4 74少厶H-K350(日立化成工業 (株)製)在厚度70 μπι的銅層、0·2 μηι的鎳層、10 μηι的 銅層構成的3層金屬箔(日本電解(株)製)的70 μιη的銅 層形成圖案,再使用鹼性蝕刻液工一 7。口七只7 7夕只社製,含氨銅醋鹽20〜30重量°/〇、氯化氨10〜20 重量%及氨1〜1 〇重量%)選擇性蝕刻銅層’在鎳層上形成 由複數個Φ2 5 0 的銅形成的金屬柱。再選擇性蝕刻去除 鎳層,留下銅金屬柱下的部分,形成由銅層及鎳層形成的 柱狀的外部連接端子。接著’爲了使其與樹脂的密接性較 佳,在露出的厚度1 0 的銅層表面及外部連接端子表面 ,以線速度i·75 m/min、噴霧壓力9·8 x 1〇4 ?3的條件’ -56- (52) 2004028123-layer metal foil consisting of 7's K '歹 4, 74's H-K350 (manufactured by Hitachi Chemical Industries, Ltd.), a copper layer with a thickness of 70 μm, a nickel layer with 0.2 μm, and a copper layer with 10 μm A 70 μm copper layer (manufactured by Nippon Electrolytic Co., Ltd.) was patterned, and an alkaline etching solution was used. Mouth seven, seven and seven made by the company, containing ammonia copper vinegar salt 20 ~ 30% by weight / 0, ammonia chloride 10 ~ 20% by weight, and ammonia 1 ~ 10% by weight) selectively etch the copper layer 'on the nickel layer A metal pillar formed of a plurality of copper of Φ2 5 0 is formed. Then, the nickel layer is selectively removed by etching, leaving a portion under the copper metal pillar to form a columnar external connection terminal formed by the copper layer and the nickel layer. Then, in order to make the adhesiveness with the resin better, the exposed copper layer surface and the external connection terminal surface with a thickness of 10, a linear velocity of i · 75 m / min, and a spray pressure of 9 · 8 x 104 · 3 Conditions' -56- (52) 200402812

施加化學處理的表面粗化處理劑之NBDII處理液(使用荏 原電產(株)製,含硫酸7.5重量%、磷酸3.8重量%、過氧 化氫4.0重量%)的處理,加以粗化,在外部連接端子的表 面及側面、露出的厚度1 〇 μηι的銅層表面,獲得平均2 μηι的粗化面。在此形成外部連接端子的金屬箔的外部連 接端子側,以印刷機VE - 5 00 (東k工 &gt;二7 y &gt; / ( 株)製)印刷,對銅的密接性較鎳佳的液狀的矽變性聚醯 胺亞胺樹脂的絕緣樹脂KS6600 (日立化成工業(株)製), 埋沒外部連接端子後,進行以8 0 °C加熱3 0分鐘的乾燥, 使其成B階段狀態。用市售的硏磨紙硏磨,直到埋設的外 部連接端子的端面出現後,以180°C 30分鐘+ 22 0 °C 30A chemically treated surface roughening agent NBDII treatment solution (using EBARA Corporation, containing 7.5% by weight of sulfuric acid, 3.8% by weight of phosphoric acid, and 4.0% by weight of hydrogen peroxide) was treated and roughened externally. The surface and sides of the connection terminals and the surface of the exposed copper layer with a thickness of 10 μm were obtained to obtain a roughened surface with an average of 2 μm. Here, the external connection terminal side of the metal foil forming the external connection terminal is printed with a printing press VE-5 00 (manufactured by TOKYO & Co., Ltd.), and its adhesion to copper is better than that of nickel. Liquid silicon modified polyimide resin insulation resin KS6600 (manufactured by Hitachi Chemical Co., Ltd.), after burying the external connection terminals, drying at 80 ° C for 30 minutes to make it into a B-stage state . Honed with a commercially available honing paper until the end face of the buried external connection terminal appeared, at 180 ° C for 30 minutes + 22 0 ° C 30

分鐘的條件使樹脂充分硬化,而形成樹脂層。接著,使用 &gt; I亍7 7夕只社製工一 7° 口七只液構成的鹼性蝕刻液選 擇性蝕刻金屬箔的厚度1 0 μηι的銅層,形成與外部連接端 子連接的電路。然後,在電路表面及外部連接端子的露出 面形成電解鎳/金電鍍(大和電機工業(株)製),製成具 有如第13圖(〇所示截面的半導體封裝用基板(尺寸:12 X 12 mm)。在此基板,用手工黏貼晶片焊接用薄膜,安裝半 導體晶片(尺寸:8·6 X 8.6 mm)。用線焊接器HW 2100 (九 州松下電器(株)製)進行線(金線)焊接,使用液狀密封劑 (HIR 3 000,日立化成工業(株)製),以硬化條件·· 8〇°C 1 小時、1 2 0 °C 1小時、1 8 0 t 1小時的分階段加熱硬化密 封後,切割成規定大小,以回流裝置焊接焊錫球,使其成 爲具有第13圖(h)所示截面的半導體封裝。 -57- (53) 200402812 在進行與上述相同的粗化處理的厚度5 〇 μπι的銅箔, 與上述问樣形成樹脂層,切出寬度1〇 mm、長度50 mm 的試驗片’用牽引試驗器對樹脂層向90 °方向剝離銅箔, 以測量樹脂層與銅箔的密接強度的結果,P C T 2 4小時後的 脫皮強度爲1·1 KN/ m。而未粗化時的脫皮強度爲0.75 KN/ m。The conditions of minutes allow the resin to harden sufficiently to form a resin layer. Next, a copper layer with a thickness of 10 μm was selectively etched using an alkaline etching solution consisting of 7 ° mouth and 7 liquids made by the company's 7-year-old company to form a circuit connected to the external connection terminal. Then, electrolytic nickel / gold plating (manufactured by Yamato Denki Kogyo Co., Ltd.) was formed on the circuit surface and the exposed surfaces of the external connection terminals to produce a semiconductor package substrate (size: 12 X) having a cross section as shown in FIG. 13 (0). 12 mm). On this substrate, a semiconductor wafer (size: 8 · 6 X 8.6 mm) was attached by hand to attach a film for wafer soldering. A wire bonder HW 2100 (made by Kyushu Matsushita Electric Co., Ltd.) was used to wire (gold wire) ) Welding using a liquid sealant (HIR 3,000, manufactured by Hitachi Chemical Co., Ltd.) under hardening conditions: 80 ° C for 1 hour, 120 ° C for 1 hour, 180 ° t for 1 hour After the step of heat-hardening and sealing, it is cut into a predetermined size, and solder balls are soldered with a reflow device to make a semiconductor package having a cross-section as shown in Fig. 13 (h). -57- (53) 200402812 The same roughening as described above is being performed. The processed copper foil having a thickness of 50 μm was formed into a resin layer with the above-mentioned sample, and a test piece having a width of 10 mm and a length of 50 mm was cut out. The copper foil was peeled from the resin layer in a 90 ° direction with a traction tester to measure the resin. Of the adhesion strength between the layer and the copper foil , P C T peeling strength after 24 hours was 1 · 1 KN / m. The peeling strength without roughening of 0.75 KN / m.

實施例7(配線板D、半導體封裝體D) 使用7才卜卜'、歹4 4少厶Η - K3 5 0 (日立化成工業( 株)製)在厚度70 μπι的銅層、0.2 μπι的鎳層、10 μπι的銅 層構成的3層金屬箔(日本電解(株)製)的70 μπι的銅層形 成圖案,再使用鹼性蝕刻液工一 7° 口七只Α7 y夕 只社製)選擇性蝕刻銅層,在露出的鎳層上形成由複數個 Φ2 5 0 μπι的銅形成的金屬柱。爲了使其與樹脂的密接性較 佳,在露出的鎳層及金屬柱表面,使用化學處理的表面粗Example 7 (wiring board D, semiconductor package D) 7 卜 ′, 歹 4 4 厶 Η 厶 Η-K3 50 (made by Hitachi Chemical Industry Co., Ltd.) on a 70 μm-thick copper layer, 0.2 μm Three layers of metal foil (manufactured by Nihon Kogyo Co., Ltd.) consisting of a nickel layer and a copper layer of 10 μm were used to form a pattern of a 70 μm copper layer, and an alkaline etchant was used to make a 7 ° opening. ) Selectively etch the copper layer to form metal pillars made of copper with a diameter of 2 50 μm on the exposed nickel layer. In order to make it have better adhesion to the resin, the surface of the exposed nickel layer and metal pillars is chemically treated with a rough surface.

化處理劑之NBDII處理液(荏原電產製)施加粗化處理。這 個時候,爲了要同時進行障壁層的鎳層的去除,將處理時 間延長爲實施例1的1 · 5倍。藉此,形成除了金屬柱下面 以外的鎳層被去除的柱狀的外部連接端子,同時,在外部 連接端子端面及側面、露出的厚度1 〇 μπι的銅層表面,與 % 實施例6同樣獲得平均2 μπι的粗化面。在此形成有外部 連接端子的金屬箔,以印刷機VE - 5 00 (東k工 &gt;二7 9 &gt; /(株)製)印刷液狀的矽變性聚醯胺亞胺樹脂的絕緣 樹脂KS 6600(日立化成工業(株)製),完全埋沒外部連接端 -58- (54) 200402812 子後’進行以8 0 °C加熱3 0分鐘的乾燥,使其成B階段狀 態。用市售的硏磨紙硏磨,直到埋設的外部連接端子的端 面出現後,以1 80°C 30分鐘+ 220 °C 30分鐘的條件使樹 脂充分硬化’而形成樹脂層。接著,與實施例6同樣形成 厚度ΙΟμιη的銅層的電路。然後,與實施例6同樣,形成 電解鎳/金電鍍(大和電機工業(株)製),製成半導體封 裝用基板。接著,與實施例6同樣,在此基板黏貼晶片焊 接用薄膜,以手工安裝半導體晶片。與實施例6同樣,用 線焊接器HW 2 100 (九州松下電器(株)製)進行線焊接, 使用液狀密封劑密封後,切割成規定大小,以回流裝置焊 接焊錫球,使其成爲半導體封裝。測量樹脂層與銅箔的密 接強度的結果,PCT24小時後的脫皮強度爲1.2KN/m。 而未粗化時的脫皮強度爲〇.75KN/m。 實施例8(配線板E、半導體封裝體E)A roughening treatment is applied to the NBDII treatment solution (manufactured by Ebara Densan). At this time, in order to remove the nickel layer of the barrier layer at the same time, the processing time was extended to 1.5 times that of Example 1. Thereby, a columnar external connection terminal with a nickel layer removed except for the lower surface of the metal pillar was formed. At the same time, the exposed end surface and side surface of the external connection terminal were exposed to the surface of the copper layer with a thickness of 10 μm in the same manner as in Example 6. Roughened surface with an average of 2 μm. The metal foil with the external connection terminals formed here was printed with a printing press VE-5 00 (manufactured by TOKYO & Co., Ltd.), and made of a liquid-modified silicone-based polyimide resin insulating resin. KS 6600 (manufactured by Hitachi Chemical Co., Ltd.) completely buryes the external connection end -58- (54) 200402812, and then heats it at 80 ° C for 30 minutes to dry it to a B-stage state. Honing with a commercially available honing paper until the end surface of the buried external connection terminal appeared, the resin was hardened sufficiently under the conditions of 1 80 ° C for 30 minutes + 220 ° C for 30 minutes' to form a resin layer. Next, a circuit of a copper layer having a thickness of 10 µm was formed in the same manner as in Example 6. Then, in the same manner as in Example 6, electrolytic nickel / gold plating (manufactured by Yamato Denki Kogyo Co., Ltd.) was formed to prepare a substrate for semiconductor packaging. Next, as in Example 6, a film for wafer bonding was stuck on this substrate to manually mount a semiconductor wafer. As in Example 6, wire bonding was performed using a wire soldering device HW 2 100 (manufactured by Kyushu Matsushita Electric Co., Ltd.), sealed with a liquid sealant, cut to a predetermined size, and solder balls were soldered by a reflow device to be a semiconductor. Package. As a result of measuring the adhesion strength between the resin layer and the copper foil, the peeling strength after PCT for 24 hours was 1.2 KN / m. The peeling strength when not roughened was 0.75 KN / m. Example 8 (wiring board E, semiconductor package E)

使用7才卜卜'、歹4 7 4少厶Η - K3 5 0(日立化成工業( 株)製)在厚度70 μηι的銅層、1 .〇 μπι的鈦層、1 8 μπι的銅 層構成的3層金屬箔(日本電解(株)製)的70 μιη的銅層形 成圖案,再使用鹼性蝕刻液工一 7° 口七7 7 V夕 只社製)選擇性蝕刻銅層,在露出的鈦層表面形成由複數 個φ2 5 0 μιη的銅形成的金屬柱。鈦是很難以銅的化學粗化 液蝕刻,因此無法在粗化處理的同時去除鈦層。因此,以 氟化氨系的蝕刻液工 &gt; 只卜U 7 7° ( &gt;少亍7 7夕只社製) 選擇性鈾刻,留下銅金屬柱下以外的部分,露出厚度18 -59- (55) 200402812 μιη的銅層表面,而在其表面形成外部連接端子。然後, 進行與實施例6同樣的粗化處理以後的作業’製成半導體 封裝。樹脂層與銅層(電路)的密接性與實施例6相同。 實施例9(配線板Ε、半導體封裝體Ε)It is composed of 7 stainless steel plates, 4 7 4 Shao-K3 50 (made by Hitachi Chemical Industry Co., Ltd.) in a copper layer with a thickness of 70 μm, a titanium layer with 1.0 μm, and a copper layer with 18 μm A 70 μm copper layer was patterned on a three-layer metal foil (manufactured by Nippon Electrochemical Co., Ltd.), and then the copper layer was selectively etched using an alkaline etching solution (7 °, 七 7, 7 7 夕 only), and then exposed. Metal pillars are formed on the surface of the titanium layer by a plurality of copper with a diameter of 2 50 μm. Titanium is difficult to etch with a chemical roughening solution of copper, so the titanium layer cannot be removed at the same time as the roughening treatment. Therefore, using an ammonia fluoride-based etching solution &gt; U 7 7 ° (&gt; Shao 7 7 Yuki Co., Ltd.) selective uranium engraving, leaving the part outside the copper metal pillar, exposing the thickness 18- 59- (55) 200402812 μm copper surface, and external connection terminals are formed on the surface. Then, the same operation as after the roughening process similar to that of Example 6 was performed 'to produce a semiconductor package. The adhesion between the resin layer and the copper layer (circuit) is the same as in Example 6. Example 9 (wiring board E, semiconductor package E)

使用7才卜Κ歹4 74少厶Η - Κ3 50(日立化成工業 (株)製)在厚度70μπι的銅層、0·2μηι的鎳層、ΙΟμπι的 銅層構成的3層金屬箔(日本電解(株)製)的70 μηι的銅層 形成圖案,再使用驗性倉虫刻液工一 7° 口七只(&gt; 儿亍7 y 夕久社製)選擇性蝕刻銅層,在露出的鎳層上形成由複數 個φ2 5 0 μηι的銅形成的金屬柱。製成選擇性蝕刻鎳層者( 比較例)與未蝕刻者(實施例)的兩種金屬薄片。對形成外 部連接端子的此兩種金屬薄片不做粗化處理,印刷樹脂後 與實施例6同樣製作,使成封裝。但是,樹脂是使用對鎳 的密接性較銅高的液狀的矽變性聚醯胺亞胺樹脂。3-layer metal foil (Japan Electrolytic Co., Ltd.) consisting of 7 KK 4 74 Shao-K3 50 (manufactured by Hitachi Chemical Co., Ltd.) with a copper layer of 70 μm thickness, a nickel layer of 0.2 μm, and a copper layer of 10 μm Co., Ltd.) to form a pattern with a 70 μm copper layer, and then use a tentative hamster engraving fluid to make a 7 ° mouth of seven (&gt; Erji 7 y Yukusha Co., Ltd.) to selectively etch the copper layer. Metal pillars are formed on the nickel layer by a plurality of copper φ 2 50 μm. Two types of metal flakes were prepared for the selective etching of the nickel layer (comparative example) and the non-etched layer (example). The two metal foils forming the external connection terminals were not subjected to roughening treatment, and were printed in the same manner as in Example 6 after the resin was printed to make a package. However, as the resin, a liquid silicon-modified polyimide resin having a higher adhesion to nickel than copper is used.

使用厚度5 0 μιη的鎳層及銅箔,以上述矽變性聚醯胺 亞胺樹脂製作與實施例6製成者同一尺寸的試驗片,分別 測量與樹脂層及銅箔的密接強度之結果,與鎳層及樹脂層 的脫皮強度爲0.7 5 KN / m。而與銅層及樹脂層的脫皮強 度爲0.5 0 KN / m,與鎳層的密接性較佳。 如以上所說明,本發明可以改善樹脂層與電路及外部 連接端子的密接強度,在具有複數個柱狀的外部連接端子 的半導體封裝用基板,可以提供可靠性高的小型半導體封 裝用基板。 -60- (56) (56)200402812 依據本發明的配線板的製造方法時,在金屬箔或配線 板用構件、半導體封裝用基板,特別有凹凸時,可以形成 沒有翹曲或成波浪狀,密接性良好的樹脂層。因此,依本 發明方法製成的配線板A及B,使用該等製造的半導體封 裝A及B,不會有翹曲或成波浪狀,其平坦性優異。 同時’由於用絕緣樹脂埋設蝕刻金屬箔形成的突塊, 形成層間連接用的金屬柱,在其直上方的電路設連接用墊 而製成基板,因此藉由簡單的配線圖案的變更,便可以提 供,小型的半導體封裝用基板C、配線板C、半導體裝置 Cl、C2、C3、半導體封裝C1及C2。 同時,在本發明的配線板D、E及半導體封裝D、E ,樹脂層與電路及外部連接端子之密接強度獲得改善,可 靠性很高。 【圖式簡單說明】 第1圖是說明藉由本發明的配線板A的製造方法, 在具有導電性突起的金屬箔形成樹脂層的製程截面圖。 第2圖是說明藉由本發明的配線板B的製造方法,在 具有導電性突起的金屬范埋入半導體晶片後,形成樹脂層 的製程,及埋入半導體晶片後’使其成爲半導體封裝用基 板的製程截面圖。 第3圖是說明將本發明的配線板B的製造方法,應用 在內部設有複數個半導體晶片的三維半導體封裝的製造方 法的製程截面圖。Using a nickel layer and a copper foil with a thickness of 50 μm, a test piece of the same size as that produced in Example 6 was prepared using the silicon-modified polyimide resin described above, and the results of measuring the adhesion strength with the resin layer and the copper foil, respectively, The peeling strength with the nickel layer and the resin layer was 0.7 5 KN / m. The peeling strength with the copper layer and the resin layer is 0.5 0 KN / m, and the adhesion with the nickel layer is better. As described above, the present invention can improve the adhesion strength between the resin layer and the circuit and the external connection terminals, and can provide a highly reliable small-sized semiconductor package substrate on a semiconductor package substrate having a plurality of columnar external connection terminals. -60- (56) (56) 200402812 According to the method for manufacturing a wiring board according to the present invention, when metal foil or a member for a wiring board or a substrate for a semiconductor package has irregularities, it can be formed without warping or wavy, Resin layer with good adhesion. Therefore, the wiring boards A and B manufactured by the method of the present invention, using these manufactured semiconductor packages A and B, have no warpage or wave shape, and have excellent flatness. At the same time, since bumps formed by etching metal foil are buried with insulating resin, metal pillars for interlayer connection are formed, and connection pads are provided on the circuit directly above them to form a substrate. Therefore, simple wiring pattern changes can be used. Provides small-sized semiconductor package substrates C, wiring boards C, semiconductor devices Cl, C2, C3, and semiconductor packages C1 and C2. At the same time, in the wiring boards D and E and the semiconductor packages D and E of the present invention, the adhesion strength between the resin layer and the circuit and the external connection terminals is improved, and the reliability is very high. [Brief description of the drawings] FIG. 1 is a cross-sectional view illustrating a process for forming a resin layer on a metal foil having conductive protrusions by the method for manufacturing a wiring board A according to the present invention. FIG. 2 illustrates a process for forming a resin layer after a semiconductor wafer having a conductive protrusion is embedded in a semiconductor wafer by the method for manufacturing a wiring board B according to the present invention, and the semiconductor wafer is embedded into a substrate for semiconductor packaging. Process cross-section. Fig. 3 is a cross-sectional view of a manufacturing process illustrating a method for manufacturing a wiring board B according to the present invention by applying a manufacturing method of a three-dimensional semiconductor package in which a plurality of semiconductor wafers are provided.

-61 - (57) (57)200402812 第4圖是本發明基板c的一個型態的部分截面圖。 第5圖是傳統的使用藉由通孔電鍍層間連接的半導體 封裝用基板的半導體封裝的截面圖。 第6圖是傳統的使用半導體封裝用基板的半導體封裝 的截面圖。 第7圖是表示使用本發明基板C的半導體封裝C1的 一個型態的截面圖。 第8圖是使用在實施例4作成的半導體封裝用基板C 作成的半導體裝置C1的配線圖案的部分平面圖。(a)表示 使用本發明的半導體封裝用基板C時的配線圖案,(b)表 示使用傳統的基板時的配線圖案。 第9圖是使用在實施例5作成的半導體封裝用基板c 作成的半導體裝置C 1的配線圖案的部分平面圖。(a)表示 使用本發明的半導體封裝用基板C時的配線圖案,(b)表 示使用傳統的基板時的配線圖案。 第10圖是表示對薄片部,及薄片部表面具有複數個 柱狀的外部連接端子的金屬薄片施加粗化的金屬薄片的截 面圖。 第11圖是表示製作第10圖所示金屬薄片的製程的一 個型態的製程圖。 第12圖是表示製作第10圖所示金屬薄片的製程的另 一個型態的製程圖。 桌圖是表藉由本發明的製造方法製作半導體封裝 D的製程的〜個型態的製程圖。 -62- (58) 200402812 [圖號說明] 1 :第1樹脂層 2 :第2樹脂層 3 :第3樹脂層 4 :硬化第1樹脂層 5 :硬化第2樹脂層 6 :硬化第3樹脂層-61-(57) (57) 200402812 Fig. 4 is a partial cross-sectional view of one form of the substrate c of the present invention. Fig. 5 is a cross-sectional view of a conventional semiconductor package using a semiconductor package substrate connected by interlayer plating through-holes. Fig. 6 is a cross-sectional view of a conventional semiconductor package using a semiconductor package substrate. Fig. 7 is a cross-sectional view showing one embodiment of a semiconductor package C1 using a substrate C of the present invention. FIG. 8 is a partial plan view of a wiring pattern of a semiconductor device C1 prepared using the semiconductor package substrate C prepared in Example 4. FIG. (A) shows a wiring pattern when the semiconductor package substrate C of the present invention is used, and (b) shows a wiring pattern when a conventional substrate is used. Fig. 9 is a partial plan view of a wiring pattern of a semiconductor device C1 prepared using the semiconductor package substrate c prepared in Example 5. (A) shows a wiring pattern when the semiconductor package substrate C of the present invention is used, and (b) shows a wiring pattern when a conventional substrate is used. Fig. 10 is a cross-sectional view showing a thin metal plate and a metal thin film having a plurality of columnar external connection terminals on the surface of the thin film portion, wherein the metal thin film is roughened. Fig. 11 is a process diagram showing one form of a process for producing the metal sheet shown in Fig. 10; Fig. 12 is a process diagram showing another type of the process of manufacturing the metal sheet shown in Fig. 10; The table chart is a process chart of various types showing the manufacturing process of the semiconductor package D by the manufacturing method of the present invention. -62- (58) 200402812 [Description of drawing number] 1: first resin layer 2: second resin layer 3: third resin layer 4: hardened first resin layer 5: hardened second resin layer 6: hardened third resin Floor

7 :具有導電性突起的金屬箔 A :導電性突起 8 :配線 9 :金突塊 1 0 :半導體晶片 B : AI電極 C :電路7: Metal foil with conductive protrusion A: Conductive protrusion 8: Wiring 9: Gold bump 10: Semiconductor wafer B: AI electrode C: Circuit

1 1 :藉由添加法形成的配線圖案 1 2 :抗蝕劑 1 3 :塡底材 1 4 :玻璃環氧基材 1 5 :通孔電鍍連接部 1 6 :鎳/金電鍍墊 1 7 :擠壓機 1 8 :掩罩 1 9 :晶片焊接糊漿 2 0 :導電性糊漿 -63- (59)200402812 101:設在金屬柱直上方的電路之連接用墊 1 02 :設在絕緣樹脂上的電路之連接用墊 1 〇 3 :金屬柱 1 〇 4 :貫穿孔電鍍連接部 105 :半導體晶片 1 0 6 :絕緣樹脂層 107 :金弓[線1 1: Wiring pattern formed by the additive method 1 2: Resist 1 3: Plutonium substrate 1 4: Glass epoxy substrate 1 5: Through-hole plated connection portion 16: Nickel / gold plated pad 1 7: Extruder 18: Mask 19: Wafer solder paste 2 0: Conductive paste -63- (59) 200402812 101: Pad for connection of a circuit provided directly above a metal pillar 1 02: Provided in an insulating resin Pads for connection of the upper circuit 〇3: metal pillars 〇4: through-hole plated connection 105: semiconductor wafer 106: insulating resin layer 107: gold bow [wire

1 〇 8 :密封材 109: Ni/Au 電鍍 1 1 0 :焊錫突塊 1 1 1 :電路 1 1 2 :抗焊錫劑 1 1 3 :電路 W :薄片部1 8: Sealing material 109: Ni / Au plating 1 1 0: Solder bump 1 1 1: Circuit 1 1 2: Solder resist 1 1 3: Circuit W: Sheet portion

X :外部連接端子 Y :金屬柱 201 :第1金屬層 202 :第2金屬層 203 :第3金屬層 204 :粗化面 205 :樹脂 Z :樹脂層 2 〇 6 :電路 207 :鎳/金電鍍 -64 - (60) (60)200402812 2 0 8 :晶片焊接薄膜 209 :半導體晶片 2 1 0 ·金引線 2 1 1 :密封材 2 1 2 :焊錫球X: external connection terminal Y: metal pillar 201: first metal layer 202: second metal layer 203: third metal layer 204: roughened surface 205: resin Z: resin layer 2 06: circuit 207: nickel / gold plating -64-(60) (60) 200402812 2 0 8: Wafer bonding film 209: Semiconductor wafer 2 1 0 · Gold lead 2 1 1: Sealing material 2 1 2: Solder ball

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Claims (1)

200402812 Π) 拾、申請專利範圍 1 · 一種配線板的製造方法,其特徵爲:包含, 在表面有複數個導電性突起的絕緣構件,藉由印刷塗 抹硬化前的流動狀淸漆狀態的絕緣樹脂,塗抹到導電性突 起被絕緣樹脂埋沒的厚度的印刷製程;令印刷的絕緣樹脂 硬化的硬化製、程;以及,硏磨絕緣樹脂使導電性突起的前 端露出的硏磨製程。200402812 Π) Scope of patent application 1 · A method for manufacturing a wiring board, comprising: an insulating member having a plurality of conductive protrusions on its surface; and a printing varnished insulating resin before being hardened by printing. A printing process that is applied to a thickness where the conductive protrusion is buried by the insulating resin; a hardening process that hardens the printed insulating resin; and a honing process that hones the insulating resin to expose the tip of the conductive protrusion. 2 .如申請專利範圍第1項所述之配線板的製造方法, 其中 配線板爲半導體封裝用基板。 3 ·如申請專利範圍第1項所述之配線板的製造方法, 其中 配線構件爲表面具有複數個導電性突起的金屬箔。 4·如申請專利範圍第1項所述之配線板的製造方法, 其中2. The method for manufacturing a wiring board according to item 1 of the scope of patent application, wherein the wiring board is a substrate for a semiconductor package. 3. The method for manufacturing a wiring board according to item 1 of the scope of patent application, wherein the wiring member is a metal foil having a plurality of conductive protrusions on its surface. 4. The method for manufacturing a wiring board according to item 1 of the scope of patent application, wherein 配線構件爲:絕緣樹脂層、絕緣樹脂層兩面上的層間 相互連接的導體層;及絕緣樹脂層的至少一面上有導電性 突起者。 5 ·如申請專利範圍第1項所述之配線板的製造方法, 其中 在硬化製程後進行硏磨製程。 6·如申請專利範圍第1項所述之配線板的製造方法, 其中 包含:在表面有複數個導電性突起的絕緣構件,藉由 -66- (2) 200402812 印刷塗抹硬化前的流動狀淸漆狀態的絕緣樹脂,塗 電性突起被絕緣樹脂埋沒的厚度的印刷製程;將印 緣樹脂乾燥到失去流動性,但是在完全硬化以前之 狀態的乾燥製程;硏磨乾燥到半硬化狀態的絕緣樹 導電性突起的前端露出的硏磨製程;硏磨後令絕緣 全硬化的硬化製程。 7.如申請專利範圍第〗項所述之配線板的製造 其中 包含:在配線構件的具有導電性突起的面,印 動狀淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性 在完全硬化以前之半硬化狀態,再按順序分別印刷 與絕緣樹脂(1)不同,呈流動狀淸漆狀態的絕緣樹 及成分與絕緣樹脂(2)不同,呈流動狀淸漆狀態的 脂(3)的至少兩種絕緣樹脂,乾燥到失去流動性, 完全硬化以前之半硬化狀態,藉此將由絕緣樹脂 絕緣樹脂(2)層及絕緣樹脂(3)層之至少3層所構成 絕緣樹脂層,形成爲導電性突起被絕緣樹脂埋沒的 製程;令多層絕緣樹脂層中的所有絕緣樹脂同時完 的硬化製程;以及,硏磨多層絕緣樹脂層使導電性 前端露出的硏磨製程。 8 .如申請專利範圍第7項所述之配線板的製造 其中 在硏磨製程後進行硬化製程。 9.如申請專利範圍第7項所述之配線板的製造 抹到導 刷之絕 半硬化 脂,使 樹脂完 方法, 刷呈流 ,但是 ,成分 脂(2), 絕緣樹 但是在 (1)層、 的多層 厚度的 全硬化 突起的 方法, 方法, -67- (3) (3)200402812 其中 在形成多層絕緣樹脂層的製程中,絕緣樹脂(i)使用 與配線構件的接著性良好的絕緣樹脂,包含絕緣樹脂 層及絕緣樹脂(3 )層的第2層以上的各層則使用,具有可 以降低製作的配線板發生翹曲的特性的絕緣樹脂。 1 0·如申請專利範圍第7項所述之方法,其中 在形成多層絕緣樹脂層的製程中,藉由印刷以任意位 置、形狀、厚度,形成無機或有機粒子的含有率互異的樹 脂、或基本樹脂構造不相同的樹脂,然後,堆疊樹脂,藉 此形成,性質互異的樹脂混合存在於絕緣樹脂中的任意處 所的樹脂層。 1 1 . 一種配線板,其特徵爲:是藉由申請專利範圍第1 〜1 〇項中任一項所述的方法製成。 12. —種半導體封裝用基板,其特徵爲:是藉由申請 專利範圍第1〜1 0項中任一項所述的方法製成。 1 3 . —種半導體封裝,其特徵爲:使用申請專利範圍 第1 2項所述之半導體封裝用基板。 1 4 . 一種製造方法,是將電子零件安裝於配線板後以 絕緣樹脂埋沒,形成絕緣樹脂層,在絕緣樹脂層上設配線 ,內設元件型的配線板的製造方法’其特徵爲:將電子零 件安裝於配線板後,藉由印刷塗抹硬化前的流動狀淸漆狀 態的絕緣樹脂埋沒電子零件,令印刷的絕緣樹脂硬化,形 成絕緣樹脂層。 1 5 .如申請專利範圍第1 4項所述之方法,其中 -68- (4) (4)200402812 電子零件是半導體晶片,內設元件型的配線板是內設 元件型的半導體封裝。 1 6 .如申請專利範圍第1 4項所述之配線板的製造方法 ,其中 包含:在配線構件的電子零件安裝面,印刷呈流動狀 淸漆狀態的絕緣樹脂(1 ),乾燥到失去流動性,但是在完 全硬化以前之半硬化狀態,再按順序分別印刷,成分與絕 緣樹脂(1)不同,呈流動狀淸漆狀態的絕緣樹脂(2 ),及成 分與絕緣樹脂(2)不同,呈流動狀淸漆狀態的絕緣樹脂 的至少兩種絕緣樹脂,乾燥到失去流動性,但是在完全硬 化以前之半硬化狀態,藉此將由絕緣樹脂(1)層、絕緣樹 脂(2)層及絕緣樹脂(3)層之至少3層所構成的多層絕緣樹 脂層’形成爲導電性突起被絕緣樹脂埋沒的厚度的製程; 令多層絕緣樹脂層中的所有絕緣樹脂同時完全硬化的硬化 製程;以及,在多層絕緣樹脂層上設配線的製程。 1 7 .如申請專利範圍第1 6項所述之方法,其中 在形成多層絕緣樹脂層的製程後,將多層絕緣樹脂層 的表面硏磨成平坦後進行硬化製程。 1 8 ·如申請專利範圍第1 6項所述之配線板的製造方法 ,其中 在形成多層絕緣樹脂層的製程中,絕緣樹脂(1)使用 與配線板及電子零件的接著性良好的絕緣樹脂,包含絕緣 樹脂(2)層及絕緣樹脂(3)層的第2層以上的各層則使用, 具有可以降低製作的內設元件型的配線板發生翹曲的特性 -69- (5) (5)200402812 的絕緣樹脂。 19·如申請專利範圍第i6項所述之方法,其中 在开7成多層絕緣樹脂層的製程中,藉由印刷以任意位 置狀厚度’形成無機或有機粒子的含有率互異的樹 脂、或基本樹脂構造不相同的樹脂,然後,堆疊樹脂,藉 此形成’性質互異的樹脂混合存在於絕緣樹脂中的任意處 所的樹脂層。 2 0·—種內設元件型配線板,其特徵爲:是藉由申請 專利範圍第1 4〜1 9項中任一項所製造。 21·—種內設元件型半導體封裝,其特徵爲:是藉由 申請專利範圍第1 4〜1 9項中任一項所製造。 22·—種基板,其特徵爲:具有,絕緣樹脂層;埋沒 在絕緣樹脂層中,貫穿到絕緣樹脂層兩面的層間連接用金 屬柱;及在金屬柱的直上方,形成在絕緣樹脂層的至少一 面上的電路’金屬柱是藉由蝕刻金屬箔而形成,連接用墊 設在金屬柱直上方的電路上。 23·如申請專利範圍第22項所述之基板,其中 電路是在金屬柱的直上方,形成於絕緣樹脂層的一面 上的金屬層。 2 4.如申請專利範圍第23項所述之基板,其中 金屬柱由第1金屬構成,電路由蝕刻條件與第1金屬 不同的第2金屬構成,金屬箔具有第1金屬層及第2金屬 層,絕緣樹脂層、電路及金屬柱是藉由’選擇性蝕刻金屬 箔的第1金屬層,在第2金屬層上形成成爲金屬柱的第1 -70- (6) (6)200402812 金屬的突塊,在第2金屬層的形成第1金屬突塊的面上, 形成第1金屬突塊露出前端面狀埋沒在絕緣樹脂中的絕緣 樹脂層,接著,選擇性蝕刻第2金屬層以形成電路,而形 成。 25.如申請專利範圍第23項所述之基板,其中 金屬柱由第1金屬層及蝕刻條件與第1金屬層不同的 第2金屬層構成,電路由蝕刻條件與第2金屬層不同的第 3金屬層構成,金屬箔以第2金屬層爲中間層具有第1金 屬層、第2金屬層及第3金屬層,絕緣樹脂層、電路及金 屬柱是藉由,選擇性蝕刻金屬箔的第1金屬層,在第2金 屬層上形成第1金屬的突塊,接著,選擇性蝕刻金屬箔的 第2金屬層,形成成爲金屬柱的第1金屬層及第2金屬層 構成的突塊,接著,在金屬箔的形成金屬突塊的面上,形 成由第1金屬層及第2金屬層構成的金屬突塊露出前端面 狀埋沒在絕緣樹脂中的絕緣樹脂層,接著,選擇性蝕刻第 3金屬層以形成電路,而形成。 2 6 ·如申請專利範圍第2 3項所述之基板,其中 金屬柱由第1金屬構成’電路由蝕刻條件與第1金屬 層不同的第2金屬層及蝕刻條件與第2金屬層不同的第3 金屬層構成,金屬箔以第2金屬層爲中間層具有第1金屬 層、第2金屬層及第3金屬層,絕緣樹脂層、電路及金屬 柱是藉由’選擇性蝕刻金屬箔的第1金屬層,在第2金屬 層上形成成爲金屬柱的第1金屬的突塊,在第2金屬層的 形成第1金屬的突塊的面上,形成第1金屬的突塊露出前 -71 - (7) (7)200402812 端面狀埋沒在絕緣樹脂中的絕緣樹脂層,接著,分別選擇 性蝕刻第3金屬層及第2金屬層以形成電路,而形成。 2 7 . —種半導體封裝用基板,其特徵爲:具有,絕緣 樹脂層;埋沒在絕緣樹脂層中,貫穿到絕緣樹脂層兩面的 層間連接用金屬柱;及在金屬柱的直上方,形成在絕緣樹 脂層的至少一面上的電路,金屬柱是藉由蝕刻金屬箔而形 成,連接用墊設在金屬柱直上方的電路上。 28. —種半導體裝置,其特徵爲:具備有,申請專利 範圍第22〜26項中任一項所述的基板及搭載於基板的半 導體晶片,在基板的金屬柱直上方,設於電路上的連接用 墊與半導體晶片的連接用墊,藉由線焊接連接在一起。 2 9.—種半導體裝置,其特徵爲:具備有,申請專利 範圍第22〜26項中任一項所述的基板及搭載於基板的半 導體晶片,在基板的金屬柱直上方,設於電路上的連接用 墊與半導體晶片的連接用墊,藉由倒裝晶片焊接連接在一 起。 3 0.—種半導體裝置,其特徵爲:具備有,申請專利 範圍第22〜26項中任一項所述的基板及搭載於基板的電 子零件,電子零件的外部連接端子在基板的金屬柱直上方 ,與設在電路上的連接用墊,在該連接用墊上連接在一起 〇 3 1 . —種半導體封裝,其特徵爲:是密封申請專利範 圍第28項所述的半導體裝置的半導體晶片搭載面側而成 -72· (8) (8)200402812 3 2 · —種半導體封裝,其特徵爲:是密封申請專利範 圍第29項所述的半導體裝置的半導體晶片搭載面側而成 〇 3 3 · —種配線板,其特徵爲:具備有,樹脂層、樹脂 層的至少一面上的電路;從電路至樹脂層的相反面,突出 在樹脂層中的複數個柱狀的外部連接端子,電路及外部連 接端子之接觸樹脂層的表面經過粗化處理。 3 4 .如申請專利範圍第3 3項所述之配線板,其中 電路與樹脂層接觸的層,是使用與樹脂層的密接性良 好的金屬層。 3 5 ·如申請專利範圍第3 3項所述之配線板,其中 電路與樹脂層接觸的層,是使用容易粗化的金屬層。 3 6.如申請專利範圍第3 3〜3 5項中任一項所述之配線 板,其中 該配線板可當作半導體封裝體用基板使用。 3 7 ·—種半導體封裝體,其特徵爲··具備有,申請專 利範圍第3 3〜3 5項中任一項所記載的配線板;搭載於配 線板的半導體晶片;及用以密封配線板的半導體晶片搭載 面的密封材料。 3 8 ·如申請專利範圍第3 3項所述之配線板的製造方法 ,其中 對具有薄片部及從薄片部的一面突出的複數個柱狀的 外部連接端子的金屬薄片,將其具有外部連接端子的表面 粗化’在金屬薄片的經粗化的表面上,形成外部連接端子 -73- (9) (9)200402812 露出前端狀埋沒在絕緣樹脂中的絕緣樹脂層,接著’去除 一部分金屬薄片的薄片部直到樹脂層露出,藉此在樹脂層 上形成與外部連接端子連接的電路。 39. 如申請專利範圍第38項所述之配線板的製造方法 ,其中 去除依序具有第1金屬層、第2金屬層及第3金屬層 的至少3層的多層金屬箔的第1金屬層的一部分,直到露 出第2層的金屬層,而在第2金屬層的露出面形成複數個 柱狀外部連接端子,藉此製成上述金屬薄片。 40. 如申請專利範圍第39項所述之配線板的製造方法 ,其中 第2金屬層是與樹脂層的密接性很好的金屬層。 4 1 .如申請專利範圍第3 9項所述之配線板的製造方法 ,其中 第2金屬層是很容易粗化的金屬層。 42 .如申請專利範圍第3 9〜4 1項中任一項所述之配線 板的製造方法,其中 第1金屬層、第2金屬層及第3金屬層是鄰接層的蝕 刻條件互異的層,第1金屬層之部分去除是藉由蝕刻去除 ,電路之形成是藉由依序蝕刻去除第1金屬層及第2金屬 層的一部分而形成。 43.如申請專利範圍第38項所述之配線板的製造方法 ,其中 將具有:金屬層的第1層(1);在第1層的一面上的 •74- (10) (10)200402812 複數個金屬柱(2);及包含與樹脂層的密接性很好的金屬 層,形成在第1層的另一面上的一層以上的金屬層(3)的 複合金屬層之至少一層金屬層,從第1層依次去除金屬柱 下以外的部分,直到露出與樹脂層的密接性很好的金屬層 ,藉此製作金屬薄片。 44. 如申請專利範圍第38項所述之配線板的製造方法 ,其中 將具有:金屬層的第1層(1);在第1層的一面上的 複數個金屬柱(2);及包含很容易粗化的金屬層,形成在 第1層的另一面上的一層以上的金屬層(3)的複合金屬層 之至少一層金屬層,從第1層依次去除金屬柱下以外的部 分,直到露出很容易粗化的金屬層,藉此製作金屬薄片。 45. 如申請專利範圍第38項所述之配線板的製造方法 ,其中 去除依序具有第1金屬層、第2金屬層及第3金屬層 的至少3層的多層金屬箔的第1金屬層的一部分,直到露 出第2層的金屬層,而在第2金屬層的露出面形成複數個 金屬柱,接著,去除第2金屬層的金屬柱下部分以外的〜 部分,直到露出第3金屬層,藉此製成上述金屬薄片。 46. 如申請專利範圍第45項所述之配線板的製造方法 ,其中 第3金屬層是與樹脂層的密接性很好的金屬層。 47. 如申請專利範圍第45項所述之配線板的製造方法 ,其中 -75- (11) (11)200402812 第3金屬層是很容易粗化的金屬層。 48·如申請專利範圍第45〜47項中任一項所述之配線 板的製造方法,其中 第1金屬層、第2金屬層及第3金屬層是鄰接層的蝕 刻條件互異的層,第1金屬層及第2金屬層的部分去除是 藉由蝕刻去除,電路之形成是藉由蝕刻去除第3金屬層的 一部分而形成。 4 9.一種配線板,其特徵爲:具備有,樹脂層、樹脂 層的至少一面上的電路;從電路至樹脂層的相反面突出在 樹脂層中的複數個柱狀的外部連接端子,電路及外部連接 端子之與樹脂層接觸的層,是與樹脂層的密接性很好的金 屬層。 5 0.如申請專利範圍第49項所述之配線板,其中 該配線板可用作半導體封裝用基板。 5 1 . —種半導體封裝,其特徵爲:具備有,申請專利 範圍第49項所述的配線板;搭載於配線板的半導體晶片 /及用以密封配線板的半導體晶片搭載面的密封材料。 5 2.—種配線板的製造方法,是對具有薄片部及從薄 片部的一面突出的複數個柱狀的外部連接端子的金屬薄片 ,在其具有外部連接端子的表面上,形成外部連接端子露 出前端狀埋沒在絕緣樹脂中的樹脂層,接著,去除一部分 金屬薄片的薄片部直到樹脂層露出,藉此在樹脂層上形成 與外部連接端子連接的電路,如申請專利範圍第49項所 述之配線板的製造方法,其特徵爲:薄片部的突出外部端 -76- (12) (12)200402812 子的面是與樹脂層的密接性很好的金屬表面。 5 3 ·如申請專利範圍第5 2項所述之配線板的製造方法 ,其中 去除依序具有第1金屬層、與樹脂層的密接性很好的 第2金屬層及第3金屬層的至少3層的多層金屬箔的第1 金屬層的一部分,直到露出第2層的金屬層,而在第2金 屬層的露出面形成複數個柱狀外部連接端子,藉此製成上 述金屬薄片。 5 4 ·如申請專利範圍第5 2項或第5 3項所述之配線板 的製造方法,其中 第1金屬層、第2金屬層及第3金屬層是鄰接層的蝕 刻條件互異的層,第1金屬層之部分去除是藉由蝕刻去除 ,電路之形成是藉由依序蝕刻去除第2金屬層及第2金屬 層的一部分而形成。 55.如申請專利範圍第52項所述之配線板的製造方法 ,其中 將具有:金屬層的第1層(1);在第1層的一面上的 複數個金屬柱(2);及包含與樹脂層的密接性很好的金屬 層,形成在第1層的另一面上的一層以上的金屬層(3)的 複合金屬層之至少一層金屬層,從第1層依次去除金屬柱 下以外的部分,直到露出與樹脂層的密接性很好的金屬層 ,藉此製作金屬薄片。 56·如申請專利範圍第52項所述之配線板的製造方法 ,其中 -77- (13) 200402812 去除依序具有第1金屬層、第2金層 密接性很好的第3金屬層的至少3層的ί 金屬層的一部分,直到露出第2層的金層 屬層的露出面形成複數個金屬柱,接著, 的金屬柱下部分以外的一部分,直到露 此製成上述金屬薄片。 5 7 ·如申請專利範圍第5 6項所述之酉 ,其中 第1金屬層、第2金屬層及第3金局 刻條件互異的層,第1金屬餍及第2金眞 藉由蝕刻去除,電路之形成是藉由鈾刻豆 一部分而形成。 58. —種半導體封裝的製造方法’其 體晶片搭載於藉由申請專利範圍第3 8或 法製造的配線板的具有電路的一面,接_ 導體晶片搭載面。 5層及與樹脂層的 多層金屬箔的第1 ^層’而在第2金 去除第2金屬層 i第3金屬層,藉 己線板的製造方法 i層是鄰接層的蝕 s層的部分去除是 ^除第3金屬層的 :特徵爲:將半導 第52項所述之方 I1密封配線板的半 -78-The wiring member is an insulating resin layer, a conductor layer connected to each other on both sides of the insulating resin layer, and a conductive protrusion on at least one side of the insulating resin layer. 5 · The method for manufacturing a wiring board according to item 1 of the scope of patent application, wherein the honing process is performed after the hardening process. 6. The method of manufacturing a wiring board according to item 1 of the scope of patent application, which includes: an insulating member having a plurality of conductive protrusions on its surface, and flowing through -66- (2) 200402812 before printing and hardening. Insulating resin in the lacquered state, a printing process in which the electrically-coated protrusions are buried by the insulating resin; drying process in which the edge resin is dried until it loses fluidity, but before it is completely hardened; insulation that has been dried to a semi-hardened state by honing A honing process in which the tip of the conductive protrusion of the tree is exposed; a hardening process in which the insulation is fully hardened after honing. 7. The manufacturing of the wiring board according to the item in the scope of the patent application, which includes: printing the insulating resin (1) on the surface of the wiring member with conductive protrusions, and drying until the fluidity is completely lost. The semi-hardened state before hardening, and then printed in order, different from the insulating resin (1), the insulating tree in the state of flowing lacquer and the composition is different from the insulating resin (2), the grease (3) in the state of flowing lacquer. At least two kinds of insulating resins are dried until they lose fluidity and are completely hardened before the semi-hardened state, thereby forming an insulating resin layer composed of at least three layers of insulating resin (2) and insulating resin (3). It is a process in which conductive protrusions are buried by an insulating resin; a hardening process in which all insulating resins in a multilayer insulating resin layer are completed simultaneously; and a honing process in which a plurality of insulating resin layers are honed to expose a conductive tip. 8. The manufacturing of the wiring board according to item 7 of the scope of patent application, wherein the hardening process is performed after the honing process. 9. The manufacturing of wiring board as described in item 7 of the scope of the patent application, the method of applying the semi-hardened grease to the guide brush to complete the resin, the brush is flowed, but the component grease (2), the insulating tree but (1) Method and method of full-hardened protrusions of multiple layers and thicknesses, -67- (3) (3) 200402812 In the process of forming a multilayer insulating resin layer, the insulating resin (i) uses insulation with good adhesion to the wiring member Resin, which is an insulating resin layer and each layer of the second layer or more including the insulating resin (3) layer, is used, and has an insulating resin that can reduce the warpage of the produced wiring board. 10. The method according to item 7 of the scope of patent application, wherein in the process of forming the multilayer insulating resin layer, resins having mutually different contents of inorganic or organic particles are formed by printing at arbitrary positions, shapes, and thicknesses, Or the resins having different basic resin structures are stacked, thereby forming a resin layer in which resins having mutually different properties are mixed in any place in the insulating resin. 1 1. A wiring board characterized by being manufactured by the method described in any one of items 1 to 10 of the scope of patent application. 12. A substrate for a semiconductor package, characterized in that it is produced by the method described in any one of the claims 1 to 10 of the scope of patent application. 1 3. A semiconductor package characterized in that the semiconductor package substrate described in item 12 of the scope of patent application is used. 14. A manufacturing method is a method for manufacturing an electronic component wiring board in which an electronic component is mounted on a wiring board and buried with an insulating resin to form an insulating resin layer, wiring is provided on the insulating resin layer, and a component-type wiring board is provided. After the electronic component is mounted on the wiring board, the electronic component is buried with a printing varnished insulating resin before hardening, and the printed insulating resin is hardened to form an insulating resin layer. 15. The method described in item 14 of the scope of patent application, wherein -68- (4) (4) 200402812 the electronic component is a semiconductor wafer, and the wiring board with a built-in type is a semiconductor package with a built-in type. 16. The method for manufacturing a wiring board according to item 14 of the scope of patent application, comprising: printing an insulating resin (1) in a flowing state of varnish on the mounting surface of the electronic parts of the wiring member, and drying until it loses flow. It is semi-hardened before it is completely hardened, and then printed separately in sequence. The composition is different from the insulating resin (1). The insulating resin (2) is in the state of flowing varnish, and the composition is different from the insulating resin (2). At least two types of insulating resins in a flowing varnished state are dried to lose fluidity, but in a semi-hardened state before being completely hardened, whereby the insulating resin (1) layer, the insulating resin (2) layer, and the insulation are dried. A process of forming a multilayer insulating resin layer 'composed of at least 3 layers of resin (3) into a thickness where conductive protrusions are buried by the insulating resin; a hardening process in which all insulating resins in the multilayer insulating resin layer are completely hardened simultaneously; and, A process for providing wiring on a plurality of insulating resin layers. 17. The method according to item 16 of the scope of patent application, wherein after the process of forming the multilayer insulating resin layer, the surface of the multilayer insulating resin layer is honed to be flat and then the hardening process is performed. 1 8 · The method for manufacturing a wiring board according to item 16 of the scope of patent application, wherein in the process of forming the multilayer insulating resin layer, the insulating resin (1) uses an insulating resin having good adhesion to the wiring board and electronic parts. Each layer including the second layer or more including the insulating resin (2) layer and the insulating resin (3) layer is used, and has a characteristic that can reduce the warpage of the built-in type wiring board -69- (5) (5 ) 200402812 insulating resin. 19. The method as described in item i6 of the scope of patent application, wherein in the process of opening 70% of the multi-layer insulating resin layer, resins having mutually different content rates of inorganic or organic particles are formed by printing at any position and thickness, or Basic resins have different resin structures, and then the resins are stacked, thereby forming a resin layer in which resins having mutually different properties are mixed in any place in the insulating resin. 2 0 · —An internal component type wiring board is characterized in that it is manufactured by applying any one of the scope of patent applications No. 14 to 19. 21 · —A built-in type semiconductor package, which is characterized in that it is manufactured by any one of the patent application scope Nos. 14 ~ 19. 22 · —A substrate, comprising: an insulating resin layer; a metal pillar for interlayer connection buried in the insulating resin layer and penetrating to both sides of the insulating resin layer; and formed directly above the metal pillar on the insulating resin layer The circuit 'metal pillars on at least one side are formed by etching metal foil, and the connection pad is provided on the circuit directly above the metal pillars. 23. The substrate according to item 22 of the scope of patent application, wherein the circuit is a metal layer formed on one side of the insulating resin layer directly above the metal pillar. 2 4. The substrate according to item 23 of the scope of the patent application, wherein the metal pillar is composed of the first metal, the circuit is composed of the second metal having different etching conditions from the first metal, and the metal foil has a first metal layer and a second metal Layers, insulating resin layers, circuits, and metal pillars are formed from the first metal layer of the metal foil by selective etching of the metal foil, forming the first -70- (6) (6) 200402812 metal on the second metal layer. A bump is formed on the surface of the second metal layer where the first metal bump is formed, and an insulating resin layer buried in the insulating resin is exposed at the front end surface of the first metal bump, and then the second metal layer is selectively etched to form Circuit. 25. The substrate according to item 23 of the scope of the patent application, wherein the metal pillars are composed of a first metal layer and a second metal layer having different etching conditions from the first metal layer, and the circuit is composed of a second metal layer having different etching conditions from the second metal layer. 3 metal layer structure. The metal foil has a first metal layer, a second metal layer, and a third metal layer with the second metal layer as an intermediate layer. The insulating resin layer, the circuit, and the metal pillar are selectively etched by the first metal foil. 1 metal layer, forming bumps of the first metal on the second metal layer, and then selectively etching the second metal layer of the metal foil to form bumps composed of the first metal layer and the second metal layer serving as metal pillars, Next, on the surface of the metal foil on which the metal bumps are formed, an insulating resin layer in which the metal bumps composed of the first metal layer and the second metal layer are exposed at the front surface is buried in the insulating resin is formed, and then the first 3 metal layers are formed to form circuits. 2 6 · The substrate according to item 23 of the scope of the patent application, wherein the metal pillar is composed of the first metal, and the circuit is composed of a second metal layer having different etching conditions from the first metal layer and a second metal layer having different etching conditions from the second metal layer. The third metal layer is composed of the first metal layer, the second metal layer, and the third metal layer with the second metal layer as an intermediate layer. The insulating resin layer, the circuit, and the metal pillar are formed by selective etching of the metal foil. In the first metal layer, bumps of the first metal that serve as metal pillars are formed on the second metal layer. On the surface of the second metal layer on which the bumps of the first metal are formed, the bumps forming the first metal are exposed- 71-(7) (7) 200402812 An insulating resin layer whose end face is buried in an insulating resin is formed by selectively etching a third metal layer and a second metal layer to form a circuit. 2 7. A substrate for a semiconductor package, comprising: an insulating resin layer; metal pillars for interlayer connection buried in the insulating resin layer and penetrating both sides of the insulating resin layer; and formed directly above the metal pillars, For a circuit on at least one side of the insulating resin layer, a metal pillar is formed by etching a metal foil, and a connection pad is provided on the circuit directly above the metal pillar. 28. A semiconductor device comprising: a substrate according to any one of claims 22 to 26; and a semiconductor wafer mounted on the substrate, which is provided on a circuit directly above a metal pillar of the substrate. The connection pad and the connection pad of the semiconductor wafer are connected together by wire bonding. 2 9. A semiconductor device, comprising: a substrate according to any one of claims 22 to 26; and a semiconductor wafer mounted on the substrate, which is provided on a circuit directly above a metal pillar of the substrate. The connection pad and the connection pad of the semiconductor wafer are connected by flip chip bonding. 3 0. A semiconductor device, comprising: a substrate according to any one of claims 22 to 26 and an electronic component mounted on the substrate; and an external connection terminal of the electronic component is on a metal pillar of the substrate. Directly above, it is connected to a connection pad provided on the circuit, and is connected to the connection pad. 03. A semiconductor package characterized in that it is a semiconductor wafer that seals the semiconductor device described in item 28 of the patent application scope. Mounting surface side -72 · (8) (8) 200402812 3 2 · A semiconductor package characterized by sealing the semiconductor wafer mounting surface side of the semiconductor device described in item 29 of the patent application scope. 3. A wiring board characterized by comprising a circuit on at least one side of the resin layer and the resin layer; a plurality of columnar external connection terminals protruding from the resin layer from the circuit to the opposite side of the resin layer, The surfaces of the circuit and the external connection terminals that contact the resin layer are roughened. 34. The wiring board according to item 33 of the scope of patent application, wherein the layer in which the circuit is in contact with the resin layer is a metal layer with good adhesion to the resin layer. 3 5 • The wiring board according to item 33 of the scope of patent application, wherein the layer in which the circuit is in contact with the resin layer is a metal layer that is easily roughened. 3 6. The wiring board according to any one of claims 3 3 to 35 in the scope of patent application, wherein the wiring board can be used as a substrate for a semiconductor package. 37. A semiconductor package characterized by having a wiring board as described in any one of claims 3 to 35 in the patent application scope; a semiconductor wafer mounted on the wiring board; and sealing the wiring A sealing material for a semiconductor wafer mounting surface of a board. 3 8 · The method of manufacturing a wiring board according to item 33 of the scope of patent application, wherein a metal sheet having a sheet portion and a plurality of columnar external connection terminals protruding from one side of the sheet portion are externally connected The surface of the terminal is roughened 'On the roughened surface of the metal sheet, an external connection terminal is formed -73- (9) (9) 200402812 The insulating resin layer buried in the insulating resin is exposed at the front end, and then a part of the metal sheet is removed The thin film portion is exposed until the resin layer, thereby forming a circuit connected to the external connection terminal on the resin layer. 39. The method of manufacturing a wiring board according to item 38 of the scope of patent application, wherein the first metal layer of the multilayer metal foil having at least three layers of the first metal layer, the second metal layer, and the third metal layer in sequence is removed. A part of the metal layer is exposed until the metal layer of the second layer is exposed, and a plurality of columnar external connection terminals are formed on the exposed surface of the second metal layer, thereby forming the above-mentioned metal sheet. 40. The method for manufacturing a wiring board according to item 39 of the scope of patent application, wherein the second metal layer is a metal layer having good adhesion to the resin layer. 41. The method for manufacturing a wiring board according to item 39 of the scope of patent application, wherein the second metal layer is a metal layer that is easily roughened. 42. The method for manufacturing a wiring board according to any one of claims 39 to 41, wherein the first metal layer, the second metal layer, and the third metal layer have different etching conditions of adjacent layers. The first metal layer is partially removed by etching, and the circuit is formed by sequentially removing a portion of the first metal layer and the second metal layer by etching. 43. The method for manufacturing a wiring board according to item 38 of the scope of patent application, which will have: a first layer (1) of a metal layer; • 74- (10) (10) 200402812 on one side of the first layer A plurality of metal pillars (2); and at least one metal layer of a composite metal layer including one or more metal layers (3) formed on the other side of the first layer, and a metal layer having good adhesion to the resin layer, From the first layer, portions other than the metal pillars are sequentially removed until a metal layer with good adhesion to the resin layer is exposed, thereby producing a metal sheet. 44. The method for manufacturing a wiring board according to item 38 of the scope of patent application, wherein the first layer (1) having a metal layer; a plurality of metal posts (2) on one side of the first layer; and A metal layer that is easily roughened, and at least one metal layer of the composite metal layer formed on the other side of the first layer by more than one metal layer (3), and sequentially removes the part other than the metal pillar from the first layer until A thin metal layer is produced by exposing a metal layer that is easily roughened. 45. The method for manufacturing a wiring board according to item 38 of the scope of patent application, wherein the first metal layer of the multilayer metal foil having at least three layers of the first metal layer, the second metal layer, and the third metal layer in sequence is removed. Part of the metal layer until the second metal layer is exposed, and a plurality of metal pillars are formed on the exposed surface of the second metal layer, and then ~ parts other than the lower part of the metal pillar of the second metal layer are removed until the third metal layer is exposed Thus, the above-mentioned metal sheet is produced. 46. The method for manufacturing a wiring board according to item 45 of the scope of patent application, wherein the third metal layer is a metal layer with good adhesion to the resin layer. 47. The method for manufacturing a wiring board as described in Item 45 of the scope of patent application, wherein -75- (11) (11) 200402812 The third metal layer is a metal layer that is easily roughened. 48. The method for manufacturing a wiring board according to any one of claims 45 to 47 in the scope of the patent application, wherein the first metal layer, the second metal layer, and the third metal layer are layers with mutually different etching conditions of adjacent layers, The first metal layer and the second metal layer are partially removed by etching, and the circuit is formed by removing a part of the third metal layer by etching. 4 9. A wiring board, comprising: a circuit on at least one side of a resin layer and a resin layer; a plurality of columnar external connection terminals protruding from the resin layer from the circuit to the opposite side of the resin layer, and a circuit The layer in contact with the resin layer and the external connection terminal is a metal layer with good adhesion to the resin layer. 50. The wiring board according to item 49 of the scope of patent application, wherein the wiring board can be used as a substrate for a semiconductor package. 51. A semiconductor package comprising: a wiring board described in item 49 of the scope of patent application; a semiconductor wafer mounted on the wiring board; and a sealing material for sealing a semiconductor wafer mounting surface of the wiring board. 5 2. A method of manufacturing a wiring board is to form an external connection terminal on a surface of the metal plate having a thin portion and a plurality of columnar external connection terminals protruding from one side of the thin portion, on the surface having the external connection terminal. The resin layer buried in the insulating resin is exposed at the front end, and then a part of the metal foil is removed until the resin layer is exposed, thereby forming a circuit connected to the external connection terminal on the resin layer, as described in item 49 of the scope of patent application. The method for manufacturing a wiring board is characterized in that: the protruding outer end of the sheet portion is -76- (12) (12) 200402812 The surface of the sub-piece is a metal surface with good adhesion to the resin layer. 5 3 · The method for manufacturing a wiring board according to item 52 of the scope of the patent application, wherein at least the second metal layer and the third metal layer having the first metal layer in order and good adhesion to the resin layer are removed. A part of the first metal layer of the three-layer multilayer metal foil is exposed until the second metal layer is exposed, and a plurality of columnar external connection terminals are formed on the exposed surface of the second metal layer, thereby producing the above-mentioned metal sheet. 5 4 · The method for manufacturing a wiring board according to item 52 or item 53 of the scope of patent application, wherein the first metal layer, the second metal layer, and the third metal layer are layers having mutually different etching conditions. The first metal layer is partially removed by etching, and the circuit is formed by sequentially removing the second metal layer and a part of the second metal layer. 55. The method for manufacturing a wiring board according to item 52 of the scope of patent application, wherein the first layer (1) having a metal layer; a plurality of metal pillars (2) on one side of the first layer; and A metal layer with good adhesion to the resin layer, at least one metal layer of the composite metal layer formed on the other side of the first layer by more than one metal layer (3), and the first layer is sequentially removed except the metal pillars. Until a metal layer with good adhesion to the resin layer is exposed, thereby producing a metal sheet. 56. The method for manufacturing a wiring board according to item 52 of the scope of application for a patent, wherein -77- (13) 200402812 removes at least the third metal layer having the first metal layer and the second gold layer in order in good adhesion. A part of the three-layer metal layer is formed into a plurality of metal pillars until the exposed surface of the second-layer gold layer metal layer is exposed. Then, a part of the metal pillars other than the lower part of the metal pillar is exposed until the above-mentioned metal sheet is formed. 5 7 · As described in item 56 of the scope of the patent application, wherein the first metal layer, the second metal layer, and the third gold layer are different in the etching conditions, and the first metal layer and the second metal layer are etched by etching. Removal, the circuit is formed by engraving a portion of the pea. 58. —A method for manufacturing a semiconductor package ’, wherein a bulk chip is mounted on a circuit-equipped surface of a wiring board manufactured by the 38th or patent application method, and is connected to a conductor chip mounting surface. 5 layers and the first metal layer of the multilayer metal foil with the resin layer, the second metal layer i and the third metal layer are removed from the second gold, and the i layer is a part of the etched layer of the adjacent layer by the manufacturing method of the wire board. Removal is to remove the third metal layer: it is characterized in that the half of the semiconductor I1 sealed wiring board described in item 52 of the semiconductor is -78-
TW092106854A 2002-05-28 2003-03-25 Substrate, wiring board, substrate for semiconductor package, semiconductor device, semiconductor package and its manufacturing method TWI228785B (en)

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JP2002219544A JP4196606B2 (en) 2002-07-29 2002-07-29 Wiring board manufacturing method
JP2002231310A JP4288912B2 (en) 2002-08-08 2002-08-08 Wiring board, semiconductor package substrate, semiconductor package, and manufacturing method thereof

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US20200227205A1 (en) * 2019-01-07 2020-07-16 Delta Electronics (Shanghai) Co., Ltd. Fabrication method for an inductor with a vertical vinding and injection molding tooling thereof
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US11909311B2 (en) 2017-05-05 2024-02-20 Delta Electronics (Shanghai) Co., Ltd Power converter, inductor element and control method of phase shedding
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