JP5580511B2 - Method for manufacturing photoelectric composite substrate - Google Patents

Description

The present invention relates to a manufacturing method of a photoelectric composite base plate provided with polymer waveguides.

  In recent years, with the rapid widening of communication infrastructure and the dramatic improvement in information processing capability of computers and the like, there is an increasing need for information processing circuits having very high-speed information transmission paths. Against this background, transmission by optical signals is being studied as one of the high-speed transmission means that exceeds the transmission speed limit of electrical signals, and a photoelectric composite substrate in which optical circuits are mixedly mounted on a circuit board such as a printed circuit board Has been developed.

  In this photoelectric composite substrate, the optical circuit exchanges light between an optical waveguide that propagates light along the substrate surface, and a photoelectric conversion element such as a laser diode or a photodiode mounted on the substrate and the optical waveguide. For this purpose, the optical coupler is composed of a micromirror or a diffraction grating having a function of changing the direction of light at an angle of 90 °.

  An optical waveguide formed on the surface of a substrate is generally a polymer waveguide formed of a clad and a core of a polymer material. A method of forming a core by patterning a photosensitive material by photolithography, a thermosetting resin, In general, it is produced by a method of forming a core by molding a thermoplastic resin with a micro mold. When forming a core by photolithography, after exposing the photosensitive material, the core is formed by developing and removing the unexposed portion and changing the refractive index of the exposed portion of the photosensitive material. (For example, refer nonpatent literature 1, patent literature 1, etc.).

In any of the above polymer waveguides, the core is surrounded by a clad, and light is propagated through the core while repeating total reflection at the interface between the core and the clad.
Toru Nakashiba, Hiroyuki Yagyu, Shinji Hashimoto, “Optical / electric composite flexible printed circuit board”, Matsushita Electric Works Technical Report, Matsushita Electric Works, Ltd., September 2006, Vol. 54, No3, p. 38-43 Japanese Patent Laid-Open No. 2001-4852

  In an optical waveguide, in order to transmit an accurate signal, it is desired that the loss of light propagating in the core is as low as possible. However, the polymer waveguide having the structure formed as described above has a core-cladding structure. There is a problem in that propagating light is easily scattered at the interface, and light escapes from the core to the clad, resulting in a large loss of light.

  That is, when the core is formed by photolithography, due to non-uniform exposure and non-uniformity during development, the surface perpendicular to the exposed surface of the core is likely to be rough, and the light propagating through the core is uneven due to the rough. It is scattered, and light escapes from the surface of the core to the cladding, resulting in light loss. Also, when the core is molded with a micro mold, the surface of the core is likely to be rough due to cutting flaws of the mold, and similarly, light escapes from the core surface to the clad and light loss occurs.

The present invention has been made in view of the above, it is an object to provide a method of manufacturing a photoelectric composite board having the light loss is low polymer waveguide.

According to a first aspect of the present invention, there is provided a method for manufacturing a photoelectric composite substrate, wherein a core polymer material is laminated on a lower clad and patterned to form a core, and a clad polymer material is laminated on the core. By forming an upper clad that covers the core, by manufacturing a photoelectric composite substrate in which a polymer waveguide comprising the core and the clad is provided on the substrate, after forming the core by patterning, before forming the upper clad, A step of laminating a low refractive polymer material having a refractive index lower than that of the core on the core and heating the low refractive polymer material to soften or melt the polymer, and then removing the low refractive polymer material; When the light is incident on one of the cores and the light is emitted from the other end of the core, the intensity distribution of the emitted light is High strength, in which at least a part in the strength in the vicinity of the interface between the cladding and forming so as to be lower.

According to the present invention, a low refractive polymer material having a lower refractive index than that of the core is laminated on the core, and the low refractive polymer material is heated to be softened or melted. The material component penetrates to form a layer having a smaller refractive index than the core, the intensity of light passing through the center of the core is high, and the intensity of light passing near the interface with the cladding of the core is low, Of the light propagating in the core, the amount of light that passes near the interface with the cladding is reduced, and even if the surface of the core is rough, it is scattered at the core-cladding interface and escapes to the cladding The amount of light is reduced, and light loss can be reduced. In addition, the low-refractive polymer material having a refractive index smaller than that of the core may be any material having a refractive index smaller than that of the core, and does not need to be transparent like the cladding polymer material. are those widens, it is manufactured easily, such shall.

According to a second aspect of the present invention, in the first aspect, the width dimension of the image obtained by imaging the light emitted from the end face of the core in the direction perpendicular to the light guiding direction from the interface with the cladding. In the range of 10% width, the intensity of the emitted light is not more than half of the intensity of the light at the center of the core.

According to the present invention, the amount of light passing through the vicinity of the interface with the clad in the core is small, and even if the surface of the core is rough, it is scattered at the interface between the core and the clad and escapes to the clad. This reduces the amount of light and can reduce optical loss.

  According to the present invention, among the light propagated in the core, the amount of light passing near the interface with the cladding is reduced, and even if the core surface is rough, it is scattered at the interface between the core and the cladding. The amount of light escaping to the cladding is reduced, and light loss can be reduced.

  Hereinafter, the best mode for carrying out the present invention will be described.

  FIGS. 1A and 1B show an example of an embodiment of a photoelectric composite substrate, in which a polymer waveguide 3 is laminated on the surface of a substrate 4 provided with a circuit 5 such as a printed wiring board. . The type of the substrate 4 may be a rigid rigid substrate having a thickness, a flexible substrate such as a film, or a mixture of rigid and flexible, The kind is not ask | required.

The polymer waveguide 3 is formed by a core 1 and a clad 2 surrounding the core 1. The core 1 is made of a core polymer material, and the clad 2 is made of a clad polymer material. The core polymer material is formed of a material having a higher refractive index than the clad polymer material. 1A and 1B, the clad 2 is formed of a lower clad 2a laminated on the surface of the substrate 4 and an upper clad 2b covering the core 1 provided on the lower clad 2a. The polymer waveguide 3 is formed by sandwiching the core 1 between the lower clad 2a and the upper clad 2b. The polymer waveguide 3 is mainly formed as a multimode waveguide, and the core 1 is formed by a pattern of signal wiring. The cross-sectional shape of the core 1 is preferably rectangular, but is not limited thereto. The size of the core 1 is not particularly limited, but the width dimension of each side of the rectangle is preferably in the range of ²⁰ to 200 μm. In the case of a shape other than the rectangle, the cross-sectional area is 400 to 40000 μm ² . A range is desirable.

  In the polymer waveguide 3 formed as described above, light is incident from one end face of the core 1 and emitted from the other end face of the core 1 as indicated by an arrow in FIG. When the emitted light is imaged on the CCD image sensor and the intensity distribution is measured, the intensity of the light emitted from the central portion is high at the end face of the core 1, and in the vicinity of the interface with the cladding 2 in the core 1. The core 1 is used so that the intensity of the light emitted from the core 1 is lowered. That is, the core 1 is formed so that light attenuation at the center is small and light attenuation near the interface with the cladding 2 is large. Therefore, the amount of light propagating through the core 1 is large in the amount of light passing through the center of the core 1, and the amount of light passing through the vicinity of the interface between the core 1 and the cladding 2 is small. The amount of light that reaches is small. Therefore, even if the surface of the core 1 is rough, the amount of light scattered by the rough unevenness is small, and the amount of light scattered at the interface between the core 1 and the clad 2 and escaping to the clad 2 is small. Therefore, the optical loss can be reduced.

  In the embodiment shown in FIG. 1A, the end face of the core 1 is exposed so that light is directly incident on and emitted from the core 1. However, an optical coupling element such as a micromirror or a diffraction grating is provided. The light may be incident / exited. The light incident on the core 1 preferably uses light whose intensity distribution is within 10% in the cross section of the core 1 and the wavelength of the light is preferably a single wavelength. In the case of having a light source, it is preferable to use a light source having a spectrum in which a light intensity of 90% or more is included in a wavelength region where the sensitivity of the CCD does not vary by 10% or more.

  Here, FIG. 1C shows an image P obtained by forming an image of light emitted from the end face of the core 1 on the CCD image sensor, and has a shape corresponding to the cross section (end face) of the core 1. It has become. In the case of FIG. 1C, the region P <b> 1 with low light intensity is formed in the vicinity of both side surfaces of the core 1, which is a surface perpendicular to the substrate 4. When the core 1 is manufactured by a photolithographic method, the core 1 is likely to be roughened on both side surfaces. Therefore, the core 1 is formed so that the attenuation of light near the both side surfaces is increased, and the light intensity is increased. Is formed in the vicinity of both side edges of the image P. The portion including the central portion between the low light intensity areas P1 is the high light intensity area P2, and the boundary between the low light intensity area P1 and the high light intensity area P2 is clear. Although not formed, the intensity of light in a region within a width W1 of 10% of the width dimension W of the image P from the side edge of the image P is less than half of the intensity of light at the center of the image P. In other words, it is preferable to set so as to be attenuated by 3 dB or more. In order for the light intensity distribution of the image P to be formed as a distribution that forms such a region P1 where the light intensity is low and a region P2 where the light intensity is high, the light intensity within the core 1 The core 1 is formed so that n1 <n2 where n1 is the refractive index of the portion corresponding to the low-area region P1, and n2 is the refractive index of the portion corresponding to the high-intensity region P2 in the core 1. To do. When the width of the core 1 is 40 μm or more, the region corresponding to the region P1 where light is attenuated by 3 dB or more in the core 1 is in the range of 5 to 10 μm from the side surface, and when the width of the core 1 is less than 40 μm , (Core width / 40) × 5 μm to (core width / 40) × 10 μm is preferable.

In the image P of FIG. 1D, the region P1 where the light intensity is low is formed by two layers of P1 ₁ and P1 ₂ , and the light intensity of the outer region P1 _{1 is} the light of the inner P1 ₂ It is smaller than the strength of. In this case, the refractive index of the portion corresponding to the region P1 ₁ where the light intensity in the core 1 is low is n1 ₁ , the refractive index of the portion corresponding to the region P1 ₂ where the light intensity in the core 1 is low is n1 ₂ , The core 1 is formed so that n1 ₁ <n1 ₂ <n2 where n2 is the refractive index of the portion corresponding to the region P2 where the light intensity within 1 is high.

  In the image P of FIG. 1 (e), the region P 1 with low light intensity is formed only in the vicinity of one side surface of the core 1. The effect can be obtained not only on both side surfaces of the core 1 but also on one side surface. In the image P of FIG. 1 (f), the regions P 1 with low light intensity are formed on both side surfaces and the top surface of the core 1. As described above, the region P1 where the light intensity is low may be any part of the surface of the core 1, or may be formed on a part of the side surface or the upper surface.

  Next, manufacture of the photoelectric composite substrate having the polymer waveguide 3 provided with the core 1 as described above will be described.

Polymeric materials for the core for forming the core 1 is to use a refractive index in size castings than cladding polymer material forming the cladding 2. The difference in the refractive index is not particularly limited, but the performance as the polymer waveguide 3 or a layer having a low refractive index is formed by immersing the component of the clad polymer material into the core 1 as described later. When doing, about 0.01-0.1 is preferable. Any material can be used as the core polymer material or the clad polymer material as long as the refractive index satisfies this relationship, but they must be of the same system, such as epoxies or acrylics. Is desirable.

  As a specific example of an epoxy-based material, a photocationic or thermal cation curing initiator is mixed with an epoxy resin that is liquid at room temperature or a mixture of an epoxy resin that is solid at room temperature and an epoxy resin that is liquid at room temperature. And a photo-curing type or thermosetting type epoxy resin material prepared by the above method. Needless to say, the present invention is not limited to this.

  When the epoxy resin that is liquid at room temperature is a main component, the core polymer material and the clad polymer material are in a liquid state. A layer can be formed.

  When an epoxy resin that is solid at room temperature is included, the epoxy resin material can be formed into a film and used as a core polymer material or a cladding polymer material. For example, by dissolving an epoxy resin material in a solvent such as anone (cyclohexane), toluene, butanone, MEK, etc., preparing a varnish, applying this varnish to the surface of a base film such as a PET film, and drying the varnish A film polymer material for the core and a polymer material for the clad can be obtained. Using the core polymer material or the clad polymer material as a film in this manner is preferable because the core 1 and the clad 2 can be formed by a laminating method, and the production of the polymer waveguide 3 becomes easy.

  FIG. 2 shows an example of a manufacturing method. First, a clad polymer material 12 is coated or laminated on the surface of a substrate 4 on which a circuit 5 such as a printed wiring board is formed, and then the clad polymer material is irradiated with ultraviolet rays. By curing 12, the lower clad 2 a is laminated on the surface of the substrate 4 as shown in FIG.

  Next, a core polymer material 11 is coated or laminated on the surface of the lower clad 2a, and a mask 21 on which a core pattern slit 20 is formed is overlaid on the core polymer material 11 as shown in FIG. By irradiating ultraviolet rays through 20, the core polymer material 11 is exposed in a core pattern. After the exposure, the core polymer material 11 is developed to remove the unexposed portion of the core polymer material 11 and the core-shaped polymer material 11 is cured to form the patterned core 1. It is formed on the surface of the lower cladding 2a as shown in FIG.

  After the core 1 is formed on the surface of the lower clad 2a in this way, a clad polymer material 12 is coated or laminated on the lower clad 2a so as to cover the core 1 as shown in FIG. Next, the clad polymer material 12 is heated and softened or melted. When the clad polymer material 12 is heated and softened or melted as described above, the refractive index of the surface layer portion of the core 1 in contact with the clad polymer material 12 becomes smaller than the original refractive index of the core 1. As described above, the refractive index of the surface layer portion of the core 1 is decreased by heating and softening or melting the clad polymer material 12 so that the monomer component in the clad polymer material 12 having a refractive index smaller than that of the core 1 The oligomer component soaks into the surface layer portion of the core 1, and the refractive index of the surface layer portion of the core 1 into which the component of the cladding polymer material 12 has soaked is reduced so as to approach the cladding polymer material 12. It is believed that there is.

  The heating temperature when the clad polymer material 12 is heat-treated is set according to the softening temperature and melting temperature of the clad polymer material 12, and is particularly limited when the clad polymer material 12 is melted. Although not intended, it is preferred that the melt viscosity be 500 to 2000 cps. The time for heat-treating the clad polymer material 12 is also arbitrarily set according to the clad polymer material 12, but is usually preferably in the range of about 10 to 60 minutes.

  After the clad polymer material 12 is heated as described above to lower the refractive index of the surface layer portion of the core 1, the clad polymer material 12 is irradiated with ultraviolet rays and cured to form the upper clad 2b. The clad polymer material 12 forming the lower clad 2a and the upper clad 2b may be the same material or different materials.

  In this way, as shown in FIG. 2E, a polymer waveguide 3 in which the core 1 is embedded in the clad 2 composed of the lower clad 2a and the upper clad 2b can be formed. In this polymer waveguide 3, when the clad polymer material 12 is heated, the core 1 is in contact with the clad polymer material 12 on both side surfaces and upper surface. A low-refractive portion is formed on the surface. Accordingly, the intensity distribution of the light of the image P obtained by focusing the light emitted from the end face of the core 1 on the CCD image sensor is as shown in FIG. The attenuation of light is larger than that of the central portion of the core 1. When the core polymer material 11 is developed to form the core 1 as shown in FIG. 2C, both side surfaces of the core 1 are roughened and uneven by the action of the developing solution. Since the vicinity of the surface has a low refractive index and the attenuation of light is large, the amount of light propagating in the core 1 passes through the vicinity of both side surfaces of the core 1 and the both sides of the core 1 are rough. The amount of light scattered on the surface is small. For this reason, the amount of light scattered at the interface between the core 1 and the clad 2 and escaping to the clad 2 is reduced, and the optical loss can be reduced. Although the thickness of the low refractive part formed in the surface layer part of the core 1 is not particularly limited, if the thickness is 5 μm or more from the surface of the core 1, the effect of reducing the optical loss can be highly obtained.

  FIG. 3 shows another example of the manufacturing method. First, the lower clad 2a is formed on the surface of the substrate 4 in the same manner as in FIG. 2A, and the lower clad 2a is formed in the same manner as in FIG. After coating or laminating the core polymer material 11 on the surface, the core 1 is formed on the surface of the lower cladding 2a as shown in FIG.

  Next, a low refractive polymer material 13 having a refractive index smaller than that of the core 1 is coated or laminated so as to cover the core 1 as shown in FIG. Next, the low refractive polymer material 13 is heated and softened or melted. When the low refractive polymer material 13 is softened or melted by heating in this way, the refractive index of the surface layer portion of the core 1 in contact with the low refractive polymer material 13 becomes smaller than the original refractive index of the core 1. In this way, the refractive index of the surface layer portion of the core 1 decreases because the low-refractive polymer material 13 is heated to be softened or melted so that the monomer component in the low-refractive polymer material 13 whose refractive index is smaller than that of the core 1 The oligomer component soaks into the surface layer portion of the core 1, and the refractive index of the surface layer portion of the core 1 into which the low refractive polymer material 13 has soaked is reduced to approach the low refractive polymer material 13. Conceivable. The heating temperature when the low-refractive polymer material 13 is heat-treated is set according to the softening temperature and melting temperature of the low-refractive polymer material 13, and is particularly limited when the low-refractive polymer material 13 is melted. Although not intended, it is preferred that the melt viscosity be 500 to 2000 cps. Moreover, the time for heat-treating the low refractive polymer material 13 is also arbitrarily set according to the low refractive polymer material 13, but is usually preferably in the range of about 10 to 60 minutes.

Thus, after the low refractive polymer material 13 is heated and the refractive index of the surface layer part of the core 1 is reduced, the low refractive polymer material 13 is removed as shown in FIG. The low refractive polymer material 13 can be removed by washing with a solvent such as a ketone such as acetone or an alcohol such as ethanol to dissolve the low refractive polymer material 13. Of course, the method is not limited to this method, and an appropriate method according to the characteristics of the low refractive polymer material 13 may be adopted.

  After that, as shown in FIG. 3C, a clad polymer material 12 is coated or laminated on the lower clad 2a so as to cover the core 1, and the clad polymer material 12 is cured by irradiating with ultraviolet rays. The clad 2b is formed.

  In this way, the polymer waveguide 3 in which the core 1 is embedded in the clad 2 composed of the lower clad 2a and the upper clad 2b can be formed. In the polymer waveguide 3, when the low refractive polymer material 13 is heated, the core 1 is in contact with the low refractive polymer material 13 on both side surfaces and top surface, so that the surface layer portions on both side surfaces and top surface of the core 1. A low-refractive portion is formed on the surface. Accordingly, the intensity distribution of the light of the image P obtained by focusing the light emitted from the end face of the core 1 on the CCD image sensor is as shown in FIG. The attenuation of light is larger than that of the central portion of the core 1. When the core 1 is formed as shown in FIG. 2C, both side surfaces of the core 1 are roughened by the action of the developing solution and have irregularities, but the vicinity of both side surfaces of the core 1 has a low refractive index. Since the attenuation of light is large, the amount of light propagating in the core 1 passes through the vicinity of both side surfaces of the core 1, and the amount of light scattered on the rough side surfaces of the core 1 is small. . For this reason, the amount of light scattered at the interface between the core 1 and the clad 2 and escaping to the clad 2 is reduced, and the optical loss can be reduced.

Incidentally, by repeatedly performing the process of FIG. 3 (a) (b), are those which can form a low refractive portion in the surface portion of the core 1 in a plurality of layers, a low refraction portion of the plurality of layers surface The refractive index can be made lower toward the side. Needless to say, the refractive index of the low refractive portion formed in the surface layer portion of the core 1 is larger than the refractive index of the cladding 2.

  Here, the low refractive polymer material 13 may be a polymer material having a refractive index smaller than that of the core 1, and any material such as an epoxy resin material may be used. Therefore, in addition to using the above-described cladding polymer material 12 as the low-refractive polymer material 13, a material having no transparency can also be used as the low-refractive polymer material 13, and the range of materials can be expanded. is there. Further, as in the embodiment of FIG. 2, the clad polymer material 12 is heated to lower the refractive index of the surface layer portion of the core 1, and then the clad polymer material 12 is further UV-cured. When the clad 2b is formed, irregularities such as waviness may occur on the surface of the upper clad 2b due to the heat treatment. In the present embodiment, the low refractive polymer material 13 is heated and the core 1 is heated. Since the low-refractive-index polymer material 13 is removed and the upper clad 2b is formed with another clad polymer material 12, the heat history is applied to the upper clad 2b. Therefore, the surface of the upper clad 2b can be formed smoothly.

  FIG. 4A shows an example of another embodiment of the photoelectric composite substrate. In this case, the refractive index of the core 1 and the clad 2 are provided at least at a part of the interface of the core 1 with the clad 2. A core surface layer portion 6 having a refractive index between the refractive indexes is provided. Other configurations are the same as those in FIG.

  In the polymer waveguide 3 formed by the core 1 provided with the core surface layer portion 6 in this way, the light of the image formed by focusing the light emitted from the end face of the core 1 on the CCD image sensor as described above. The intensity distribution is low in the portion corresponding to the core surface layer portion 6 having a lower refractive index than that of the core 1 and is high in the portion other than the core surface layer portion 6. Accordingly, the core surface layer portion 6 has a light attenuation greater than that of the central portion of the core 1, and the amount of light propagating through the core 1 passes through the core surface layer portion 6, so that the core 1 The amount of light scattered at the interface of the clad 2 and escaping to the clad 2 is reduced, and light loss can be reduced.

  4B to 4E illustrate a cross section perpendicular to the optical waveguide direction of the core 1. In the embodiment of FIG. 4B, both sides of the core 1 which are surfaces perpendicular to the substrate 4 are illustrated. Although the core surface layer portion 6 is provided on the surface, the core surface layer portion 6 may be provided only on one side surface of the core 1 as shown in FIG. The effect can be obtained not only on both side surfaces of the core 1 but also on one side surface. Moreover, you may make it provide the core surface layer part 6 in the both sides | surfaces and upper surface of the core 1 like FIG.4 (d). Thus, the core surface layer portion 6 having a low refractive index may be formed on any part of the surface of the core 1, or may be formed on a part of the side surface or the upper surface of the core 1. Further, as shown in FIG. 4E, the core surface layer portion 6 may be formed of a plurality of layers. When the core surface layer portion 6 is formed in a plurality of layers, the outer core surface layer portion 6a is formed so that the refractive index of the core surface layer portion 6a is lower than the refractive index of the inner core surface layer portion 6b. preferable. The refractive index of the core surface layer portion 6 is not necessarily a constant refractive index, and may be changed stepwise or continuously so as to decrease from the inside to the outside. The core surface layer portion 6 only needs to have a portion where the refractive index is lower than that of the central portion of the core 1.

The thickness of the core surface layer portion 6 is not particularly limited as long as it is smaller than the width of the entire core 1 including the core surface layer portion 6, but in the range of 5 to 10 μm when the width of the entire core 1 is 40 μm or more. In addition, when the entire width of the core 1 is less than 40 μm, it is preferable to set the width within the range of (core width / 40) × 5 μm to (core width / 40) × 10 μm. Further, the refractive index of the core surface layer portion 6 is not particularly limited,
(Average value of refractive index of core 1 and refractive index of clad 2) ± (refractive index of core 1−refractive index of clad 2) × 0.1
It is preferable to set in the range.

  Next, manufacture of the photoelectric composite substrate having the polymer waveguide 3 formed by the core 1 provided with the core surface layer portion 6 as described above will be described. As the core polymer material for forming the core 1 and the clad polymer material for forming the clad 2, those described above can be used.

  First, the lower clad 2a is formed on the surface of the substrate 4 in the same manner as in FIG. 2A, and the core polymer material 11 is coated or laminated on the surface of the lower clad 2a in the same manner as in FIG. 2B. The core 1 is formed on the surface of the lower clad 2a as shown in FIG. 2C by patterning by exposure and development.

  Next, as shown in FIG. 5A, a surface layer polymer material 14 having a refractive index between the refractive index of the core 1 and the refractive index of the cladding 2 is coated or laminated on the core 1. The polymer material 14 for the surface layer may be any polymer material having a refractive index between the refractive index of the core 1 and the refractive index of the cladding 2, and any material such as an epoxy resin material can be used.

  Thereafter, as shown in FIG. 5A, a mask 23 having a slit 22 wider than the core 1 is superimposed on the surface of the surface polymer material 14 and irradiated with ultraviolet rays through the slit 22 so that the surface layer is used. A portion of the polymer material 14 along the core 1 is exposed. After the exposure, the surface polymer material 14 is removed by developing the surface layer polymer material 14. The exposed portion of the surface layer polymer material 14 is cured and remains in close contact with the surface of the core 1 as shown in FIG. 5B, and the core surface layer portion 6 is formed on the core 1. Here, as a mask 21 for patterning the core 1 as shown in FIG. 2 (c), a mask 21 having a width smaller than usual is used, and the core surface layer portion 6 is formed as shown in FIG. 5 (a). As the mask 23 to be patterned, by using a normal core 1 having slits 22 formed, the total width of the core 1 and the core surface layer portion 6 can be formed to the same width as the normal core 1. Is.

  After that, as shown in FIG. 5C, a cladding polymer material 12 is coated or laminated on the lower cladding 2a so as to cover the core 1 on which the core surface layer portion 6 is formed. The upper clad 2b is formed by irradiating with ultraviolet rays and curing.

In this way, the polymer waveguide 3 in which the core 1 provided with the core surface layer portion 6 is embedded in the clad 2 composed of the lower clad 2a and the upper clad 2b as shown in FIG. 5 ( d ) is formed. It is something that can be done. In this polymer waveguide 3, core surface layer portions 6 having a refractive index lower than that of the core 1 are formed on both side surfaces and the upper surface of the core 1. Therefore, the amount of light propagating in the core 1 passes through both sides of the core 1 and the vicinity of the top surface, and the amount of light scattered on the rough side surfaces of the core 1 is small. For this reason, the amount of light scattered at the interface between the core 1 and the clad 2 and escaping to the clad 2 is reduced, and the optical loss can be reduced.

  In addition, the core surface layer part 6 can be formed with a plurality of layers by repeatedly performing the steps of FIGS.

  Next, the present invention will be specifically described with reference to examples.

(Preparation of transparent epoxy film)
-Production of transparent epoxy film A 7 parts by mass of polypropylene glycol diglycidyl ether ("PG207" manufactured by Toto Kasei Co., Ltd.), 25 masses of liquid hydrogenated bisphenol A type epoxy resin ("YX8000" manufactured by Japan Epoxy Resin Co., Ltd.) Parts, 20 parts by mass of solid hydrogenated bisphenol A type epoxy resin (“YL7170” manufactured by Japan Epoxy Resin Co., Ltd.), 1,2-epoxy-4- (2,2-bis (hydroxymethyl) -1-butanol 2-oxylanyl) cyclohexane adduct (“EHPE3150” manufactured by Daicel Chemical Industries, Ltd.), 20 parts by mass of solid bisphenol A type epoxy resin (“Epicoat 1006FS” manufactured by Japan Epoxy Resin Co., Ltd.), phenoxy resin (Toto) Kasei Co., Ltd. “YP50”) 20 parts by mass, photocation 0.5 parts by mass of a curing initiator (“SP170” manufactured by Adeka Co., Ltd.), 0.5 parts by mass of a thermal cationic curing initiator (“SI-150L” manufactured by Sanshin Chemical Industry Co., Ltd.), a surface conditioner (large “F470” manufactured by Nippon Ink Chemical Co., Ltd.) 0.1 parts by mass of each compounding component was dissolved in 30 parts by mass of toluene and 70 parts by mass of MEK, filtered through a membrane filter having a pore size of 1 μm, and then degassed under reduced pressure. By doing so, an epoxy resin varnish was prepared.

This epoxy resin varnish was coated on a PET film having a thickness of 250 μm with a bar coater, subjected to primary drying at 80 ° C. for 10 minutes, and then secondary drying at 120 ° C. for 10 minutes, so that the film thickness was 15 μm. A transparent epoxy film A formed on was prepared. The refractive index of the transparent epoxy film A is 1.54 (@ 579 nm).
-Preparation of transparent epoxy film B 42 parts by mass of liquid bisphenol A type epoxy resin ("Epicron 850S" manufactured by Dainippon Ink & Chemicals, Inc.), solid bisphenol A type epoxy resin ("Epicoat 1006FS" manufactured by Japan Epoxy Resin Co., Ltd.) ) 55 parts by mass, 3 parts by mass of a phenoxy resin (“YP50” manufactured by Toto Kasei Co., Ltd.), 1 part by mass of a cationic photocuring initiator (“SP170” manufactured by Adeka Co., Ltd.) "F470" manufactured by Co., Ltd.) 0.1 parts by mass of each compounding component dissolved in a solvent of 24 parts by mass of toluene and 56 parts by mass of MEK, filtered through a membrane filter having a pore size of 1 μm, and then degassed under reduced pressure. An epoxy resin varnish was prepared.

By forming this epoxy resin varnish into a film in the same manner as above, a transparent epoxy film B having a thickness of 40 μm was produced. The refractive index of the transparent epoxy film B is 1.59 (@ 579 nm).
-Production of transparent epoxy film C Using the epoxy resin varnish used for the production of the above transparent epoxy film A, a transparent epoxy film C having a film thickness of 55 m was produced by forming into a film in the same manner as described above. The refractive index of the transparent epoxy film C is 1.54 (@ 579 nm).
Preparation of transparent epoxy film D 20 parts by mass of bisphenol F type epoxy resin (“YDF175S” manufactured by Toto Kasei Co., Ltd.), 20 parts by mass of bisphenol A type epoxy resin (“Epicoat 1006” manufactured by Japan Epoxy Resin Co., Ltd.), solid 20 parts by mass of hydrogenated bisphenol A type epoxy resin (“YL7170” manufactured by Japan Epoxy Resin Co., Ltd.), 20 parts by mass of phenoxy resin (“YP50” manufactured by Toto Kasei Co., Ltd.), butyral resin (Electrochemical Industry Co., Ltd.) "Denkabutyral 3000-1") 5 parts by mass, photocationic curing initiator ("SP170" manufactured by Adeka Co., Ltd.) 1 part by mass, thermal cationic curing initiator (Sanshin Chemical Industry Co., Ltd. "SI-150L" “) 1 part by mass of each compounding component is dissolved in 30 parts by mass of toluene and 70 parts by mass of MEK, and the membrane has a pore size of 1 μm After filtration down filter, by vacuum degassing, to prepare an epoxy resin varnish.

  By forming this epoxy resin varnish into a film in the same manner as described above, a transparent epoxy film D having a film thickness of 40 μm was produced. The refractive index of the transparent epoxy film D is 1.56 (@ 579 nm).

Example 1
By using double-sided copper-clad flexible material ("FELIOS" manufactured by Matsushita Electric Works Co., Ltd.), patterning is performed on one side of the copper foil to form the circuit 5, and by etching and removing the other side of the copper foil, A printed wiring board 4 was produced. Then, as shown in FIG. 6 (a), the substrate 4 with the circuit 5 is overlapped with the holding plate 26 via an adhesive material 25 (PETG sheet: “Rivester” manufactured by Riken Technos), and between the stainless steel plates 27. The substrate 4 was temporarily bonded to and bonded to the holding plate 26 as shown in FIG. 6B by pressing under conditions of 160 ° C. and 0.4 MPa for 30 minutes.

  Next, a transparent epoxy film A is used as the clad polymer material 12, and this transparent epoxy film A is laminated on the surface of the substrate 4 and laminated by pressing under conditions of 60 ° C., 0.2 MPa, 120 seconds, and an ultrahigh pressure. By irradiating 2000 mJ (@ 365 nm) ultraviolet rays with a mercury lamp, the lower clad 2 a was formed on the surface of the substrate 4 as shown in FIG.

  Next, a transparent epoxy film B is used as the polymer material 11 for the core, and the transparent epoxy film B is stacked on the surface of the lower clad 2a and pressed under the conditions of 60 ° C., 0.2 MPa, 120 seconds to obtain FIG. Laminated as follows.

  Next, using the photomask 21 provided with 20 slits 20 having a width of 40 μm and a length of 110 mm at intervals of 250 μm, while positioning the positioning marks formed on both the substrate 4 and the photomask 21 with a reflection microscope, A photomask 21 is brought into close contact with the surface of the transparent epoxy film B, and irradiated with 2000 mJ (@ 365 nm) of ultraviolet light with an ultrahigh pressure mercury lamp adjusted to parallel light as shown in FIGS. 6 (e) and 8 (a). By doing so, the part corresponding to the slit 20 of the transparent epoxy film B was UV-cured.

  And by developing using toluene and Freon alternative water-based detergent ("Clean Through" manufactured by Kao Corporation) as a developer, the unexposed part of the transparent epoxy film B is dissolved and removed, and further dried, The core 1 was formed as shown in FIGS. 6 (f) and 8 (b). When the side surface of the core 1 formed in this way was observed with a microscope, it was confirmed that a lot of roughness was generated.

  Next, V-groove processing was performed at both ends in the longitudinal direction of each core 1 formed as described above. That is, as shown in FIG. 6 (g), a rotating blade 29 having a cutting blade apex angle of 90 ° (“# 5000” blade manufactured by Disco Corporation) is used, the rotational speed is 10,000 rpm, the processing speed is 0.1 mm / second, and the core A V-groove 30 having a depth of 90 μm was formed at a position of 5 mm from both ends of 1. Furthermore, gold was vacuum-deposited by covering a metal mask in which only the portion of the V-groove 30 was opened, thereby forming a micromirror 31 with a gold thin film on the surface of the V-groove 30 as shown in FIG.

  Next, a transparent epoxy film C is used as the polymer material 12 for cladding, and the transparent epoxy film C is placed on the core 1 and stacked and pressed under the conditions of 60 ° C., 0.2 MPa, 120 seconds, so that FIG. ).

  Then, this was put into an oven and the transparent epoxy film C was heat-treated at 140 ° C. for 30 minutes (a state where the heat treatment is performed is shown in FIG. 7B). During the heat treatment, the transparent epoxy film C was in a molten state.

  Next, after taking out from the oven and cooling to room temperature, the transparent epoxy film C is cured with ultraviolet rays by irradiating ultraviolet rays of 2000 mJ (@ 365 nm) with an ultra-high pressure mercury lamp as shown in FIG. 2b was formed.

  Then, the substrate 4 is peeled off from the holding plate 26, and is taken out after being subjected to heat treatment for 1 hour in an oven at 140 ° C., thereby removing the clad 2 comprising the lower clad 2a and the upper clad 2b as shown in FIG. A photoelectric composite substrate in which the polymer waveguide 3 formed by embedding the core 1 therein was provided on the surface of the substrate 4 with the circuit 5 was obtained.

(Comparative Example 1)
The steps of FIG. 6A to FIG. 7A were performed in the same manner as in Example 1 until the transparent epoxy film C was laminated from above the core 1.

  Next, without performing the heat treatment of FIG. 7B, a photoelectric composite substrate was obtained in the same manner as in FIGS. 7C and 7D.

  About the photoelectric composite substrate obtained in Example 1 and Comparative Example 1 as described above, both end surfaces of the core 1 are exposed by cutting away the end portions from the micromirror 31, and both end surfaces of the core 1 are mirror-finished. did. Then, as shown in FIG. 11, light having a wavelength of 850 nm is incident from one end face of the core 1 from the LED light emitting device 32, the intensity of the light emitted from the other end face of the core 1 is measured by the power meter 33, and guided. Wave loss was evaluated. As a result, the waveguide loss of Example 1 is 0.4 dB / cm, and the waveguide loss of Comparative Example 1 is 1.0 dB / cm. As in Example 1, the process of FIG. It was confirmed that the effect of reducing light loss can be obtained by heat-treating the transparent epoxy film C.

  Further, in the case of the first embodiment, light incident from one end face of the core 1 and light emitted from the other end face of the core 1 was photographed with a CCD camera. It was confirmed that a layer having a low strength was formed.

(Example 2)
7A in Example 1 except that the transparent epoxy film D is used instead of the transparent epoxy film C as the clad polymer material 12 in the process of FIG. A substrate was obtained.

Example 3
The steps of FIGS. 6A to 7B were performed in the same manner as in Example 1 until the transparent epoxy film C laminated on the core 1 was heated.

  Next, the uncured transparent epoxy film C was dissolved and removed as shown in FIG. 9B by putting it in an ultrasonic cleaning tank 35 filled with isopropyl alcohol as shown in FIG. .

  Next, a transparent epoxy film D is used as the clad polymer material 12, and the transparent epoxy film D is placed on the core 1 and stacked, and pressed under the conditions of 60 ° C., 0.2 MPa, 120 seconds to obtain FIG. Laminated as in c).

  Thereafter, as shown in FIG. 9 (d), 2000 mJ (@ 365 nm) of ultraviolet light was irradiated with an ultrahigh pressure mercury lamp, whereby the transparent epoxy film D was cured with ultraviolet light to form the upper clad 2b.

  Then, similarly to Example 1, the substrate 4 was peeled off from the holding plate 26 and subjected to heat treatment to obtain a photoelectric composite substrate.

  Thus, about the photoelectric composite board | substrate obtained in Example 2 and Example 3, when the waveguide loss of the core 1 was evaluated similarly to said FIG. 11, the thing of Example 2 is 0.5 dB. / Cm, the value of Example 3 was 0.4 dB / cm, and both obtained good results.

  Further, regarding the photoelectric composite substrates of Example 2 and Example 3, when the flatness of the surface of the upper clad 2b was measured, Ra = 10 μm for Example 2 and Ra = 3 μm for Example 3. . This is because, in Example 2, since the transparent epoxy film D forming the upper clad 2b is subjected to heat treatment, undulation or the like occurs on the surface during the heat treatment, whereas in Example 3, Since the upper clad 2b is formed by laminating the transparent epoxy film D after the heat-treated transparent epoxy film C is peeled off, the upper clad 2b is not affected by the heat treatment and has high flatness. .

Example 4
The steps of FIGS. 6A to 6D were performed in the same manner as in Example 1 until the transparent epoxy film B was laminated.

  Next, using a photomask 21 provided with 20 slits 20 having a width of 25 μm and a length of 110 mm at intervals of 250 μm, while positioning the positioning marks formed on both the substrate 4 and the photomask 21 with a reflection microscope, A photomask 21 is brought into close contact with the surface of the transparent epoxy film B, and an ultraviolet ray of 2000 mJ (@ 365 nm) is irradiated with an ultrahigh pressure mercury lamp adjusted to parallel light as shown in FIG. The part corresponding to the slit 20 of the film B was cured with ultraviolet rays.

  And by developing using toluene and Freon alternative water-based detergent ("Clean Through" manufactured by Kao Corporation) as a developer, the unexposed part of the transparent epoxy film B is dissolved and removed, and further dried, The core 1 was formed as shown in FIG. When the side surface of the core 1 formed in this way was observed with a microscope, it was confirmed that a lot of roughness was generated.

  Next, a transparent epoxy film D is used as the polymer material 14 for the surface layer, and the transparent epoxy film D is placed on the core 1 and stacked and pressed under the conditions of 60 ° C., 0.2 MPa, 120 seconds, thereby FIG. Laminated as in c).

  Next, using a photomask 23 provided with 20 slits 22 having a width of 40 μm and a length of 110 mm at intervals of 250 μm, the photomask 23 is aligned on the surface of the transparent epoxy film D with the same position as the photomask 21 described above. As shown in FIG. 10D, the portion corresponding to the slit 22 of the transparent epoxy film D is irradiated by irradiating ultraviolet rays of 2000 mJ (@ 365 nm) with an ultrahigh pressure mercury lamp adjusted to parallel light. UV cured.

  And by developing with toluene and Freon alternative water-based cleaning agent (“Kao Thru” manufactured by Kao Co., Ltd.) as a developer, the unexposed part of the transparent epoxy film D is dissolved and removed, and further dried, The core surface layer portion 6 was formed as shown in FIG. The core surface layer portion 6 is formed so as to be in close contact with both side surfaces and the upper surface of the core 1. When the side surface of the core surface layer portion 6 formed in this way is observed with a microscope, many roughnesses are generated. It was confirmed.

  Thereafter, the steps of FIG. 6G, FIG. 6H, FIG. 7A, FIG. 7C, and FIG. 7D are performed in the same manner as in Example 1 (FIG. 7 ( Step b) was not carried out) to obtain a photoelectric composite substrate.

Thus, about the photoelectric composite board | substrate obtained in Example 4, when the waveguide loss of the core 1 was evaluated similarly to said FIG. 11 , it was 0.5 dB / cm and a favorable result was obtained. It was. In addition, when light incident from one end face of the core 1 and emitted from the other end face of the core 1 is photographed by a CCD camera, a layer in which the light intensity is low is formed near both side faces and the top face of the core 1. It was confirmed that it was formed.

1 shows an example of an embodiment of a photoelectric composite substrate according to the present invention, (a) is a front sectional view of the photoelectric composite substrate, (b) is a side sectional view of the photoelectric composite substrate, and (c) to (f). These are figures which show the image obtained by making it image-form on a CCD image sensor. An example of embodiment of the manufacturing method of the photoelectric composite substrate which concerns on this invention is shown, (a) thru | or (e) are sectional drawings, respectively. An example of other embodiment of the manufacturing method of the photoelectric composite board | substrate which concerns on this invention is shown, (a) thru | or (c) are sectional drawings, respectively. An example of other embodiment of the photoelectric composite substrate which concerns on this invention is shown, (a) is sectional drawing of a photoelectric composite substrate, (b) thru | or (e) is an enlarged view of a core, respectively. An example of other embodiment of the manufacturing method of the photoelectric composite board | substrate which concerns on this invention is shown, (a) thru | or (d) are sectional drawings of a photoelectric composite board | substrate, respectively. An example of the manufacturing method of the photoelectric composite board | substrate in an Example is shown, (a) thru | or (h) are front sectional drawings, respectively. An example of the manufacturing method of the photoelectric composite substrate in an Example is shown, (a) thru | or (d) are front sectional drawings, respectively. An example of the manufacturing method of the photoelectric composite board | substrate in an Example is shown, (a) (b) is side sectional drawing, respectively. An example of the manufacturing method of the photoelectric composite board | substrate in an Example is shown, (a) thru | or (d) are sectional drawings, respectively. An example of the manufacturing method of the photoelectric composite board | substrate in an Example is shown, (a) thru | or (e) are sectional drawings, respectively. It is sectional drawing which shows the evaluation method of the waveguide loss of a photoelectric composite board | substrate .

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Core 2 Clad 2a Lower clad 2b Upper clad 3 Polymer waveguide 4 Substrate 5 Circuit 6 Core surface layer part 11 Core polymer material 12 Cladding polymer material 13 Low refractive polymer material 14 Surface layer polymer material

Claims (2)

  A core polymer material is laminated on the lower clad and patterned to form a core, and a clad polymer material is laminated on the core to form an upper clad covering the core. When a photoelectric composite substrate having a polymer waveguide formed on a substrate is manufactured, a low refractive polymer material having a refractive index smaller than that of the core is laminated on the core after forming the core by patterning and before forming the upper cladding. And heating and softening or melting the low-refractive polymer material, and then removing the low-refractive polymer material. The core of the polymer waveguide is allowed to enter light from one end of the core and the other of the core. When light is emitted from the end, the intensity distribution of the emitted light is high at the center of the core and is at least one near the interface with the cladding. The photoelectric composite substrate manufacturing method, characterized in that in the strength is formed to be lower. The intensity of the emitted light in the range of 10% of the width of the image obtained by imaging the light emitted from the end face of the core in the direction perpendicular to the light guide direction from the interface with the cladding but the photoelectric composite substrate manufacturing method according to claim 1, characterized in that less than half of the intensity of light at the central portion of the core.

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