JP2013092541A - Spectroscopic module - Google Patents

Abstract

The present invention provides a highly reliable spectroscopic module.
In the spectroscopic module 1 according to the present invention, when the light L1 traveling to the spectroscopic unit 4 passes through the light passage hole 50, the light L1 passes through the light incident side unit 51 that is tapered toward the spectroscopic unit 4 side. Only the light incident on the light emission side portion 52 formed so as to face the bottom surface 51b of the incident side portion 51 is emitted from the light emission opening 52a. For this reason, since the stray light M incident on the side surface 51c and the bottom surface 51b of the light incident side portion 51 is reflected on the opposite side of the light emitting side portion 52, the stray light is prevented from entering the light emitting side portion 52. Can do. Therefore, the reliability of the spectroscopic module 1 can be improved.
[Selection] Figure 4

Description

  The present invention relates to a spectroscopic module that spectrally detects light.

  As conventional spectral modules, for example, those described in Patent Documents 1 to 3 are known. In Patent Document 1, a support body that transmits light, an incident slit portion that allows light to enter the support body, a concave diffraction grating that splits and reflects light incident on the support body, and a concave diffraction grating are used. A spectroscopic module comprising a diode for detecting reflected light is described.

JP-A-4-294223 JP 2000-65642 A JP 2004-354176 A

  However, in the spectroscopic module described in Patent Document 1, light incident from the entrance slit portion becomes stray light scattered in the support body, which may reduce the reliability of the spectroscopic module.

  Therefore, the present invention has been made in view of such circumstances, and an object thereof is to provide a highly reliable spectroscopic module and a method for manufacturing the spectroscopic module.

  In order to achieve the above object, the present invention is a spectroscopic module comprising a spectroscopic unit that splits and reflects incident light, and a photodetecting element that detects light split by the spectroscopic unit, and is a photodetection module. The element has a substrate portion in which a light passage hole through which light traveling to the spectroscopic portion passes is formed, the light passage hole defining a light incident side portion defining a light incident opening on one main surface of the substrate portion, And a light exit side portion defining a light exit opening on the other main surface of the substrate portion, the light incident side portion having a bottom surface substantially parallel to one main surface and tapering toward the other main surface. The light emission side portion has a side surface substantially perpendicular to the other main surface and is opposed to the bottom surface, and a light shielding layer is formed on the side surface of the light incident side portion. It is characterized by that.

  In this spectroscopic module, when the light traveling to the spectroscopic portion passes through the light passage hole, the light emission is formed so as to face the bottom surface of the light incident side portion that tapers toward the other main surface side of the substrate portion. Only the light incident on the side is emitted from the light exit aperture. At this time, since the light incident on the side surface and the bottom surface of the light incident side portion is reflected on the opposite side of the light emitting side portion, stray light can be prevented from entering the light emitting side portion. Therefore, it is possible to improve the reliability of the spectroscopic module.

  According to the present invention, a highly reliable spectral module can be provided.

It is a top view of the spectroscopy module which concerns on embodiment of this invention. It is sectional drawing along the II-II line | wire shown in FIG. It is a bottom view of a spectroscopic module. It is a principal part expanded sectional view which shows a light passage hole. It is a principal part enlarged plan view which shows a light passage hole. It is sectional drawing for demonstrating the process of forming a light-incidence side part. It is sectional drawing for demonstrating the process of forming a light emission side part. It is a principal part enlarged plan view corresponding to FIG. 5 which shows the modification of a light passage hole. It is a principal part enlarged plan view corresponding to FIG. 5 which shows the modification of a light passage hole. It is a principal part enlarged plan view corresponding to FIG. 5 which shows the modification of a light passage hole. It is sectional drawing corresponding to FIG. 2 which shows the spectroscopy module which concerns on 2nd Embodiment. It is a principal part expanded sectional view corresponding to FIG. 3 which shows the light passage hole which concerns on 2nd Embodiment.

Hereinafter, a preferred embodiment of a spectroscopic module according to the present invention will be described in detail with reference to the drawings. In addition, in each figure, the same code | symbol is attached | subjected to the same or an equivalent part, and the overlapping description is abbreviate | omitted.
[First Embodiment]

  As shown in FIGS. 1 and 2, the spectroscopic module 1 includes a substrate (main body portion) 2 that transmits light L1 incident from a front surface (predetermined surface) 2a and a substrate 2 that is incident from an incident surface 3a. A lens unit (main body unit) 3 that transmits the light L1, a spectroscopic unit 4 that splits and reflects the light L1 incident on the lens unit 3, and a light detection element 5 that detects the light L2 split by the spectroscopic unit 4. It is equipped with. The spectroscopic module 1 splits the light L1 into the light L2 corresponding to a plurality of wavelengths by the spectroscopic unit 4, and detects the light L2 by the light detection element 5, so that the wavelength distribution of the light L1, the intensity of the specific wavelength component, etc. It is a micro-spectral module that measures.

  The substrate 2 is formed in a rectangular plate shape (for example, a total length of 15 to 20 mm, a total width of 11 to 12 mm, and a thickness of 1 to 3 mm) using light-transmitting glass such as BK7, Pyrex (registered trademark), quartz, or plastic. Yes. On the front surface 2a of the substrate 2, a wiring 11 made of a single layer film such as Al or Au, or a laminated film such as Cr—Pt—Au, Ti—Pt—Au, Ti—Ni—Au, Cr—Au is formed. ing. The wiring 11 connects a plurality of pad portions 11a arranged at the center of the substrate 2, a plurality of pad portions 11b arranged at one end portion in the longitudinal direction of the substrate 2, and the corresponding pad portions 11a and 11b. A plurality of connecting portions 11c. Further, the wiring 11 has a light reflection preventing layer made of a single layer film such as CrO or a laminated film such as Cr—CrO on the front surface 2 a side of the substrate 2.

  The light absorption layer 13 formed on the front surface 2a of the substrate 2 is a slit (light passage slit) 13a through which the light L1 traveling to the spectroscopic unit 4 passes through a light passage hole 50 (described later) of the light detection element 5. , And an opening 13b through which the light L2 traveling to the light detection portion 5b (described later) of the light detection element 5 passes. Materials for the light absorption layer 13 include black resist, colored resin (silicone, epoxy, acrylic, urethane, polyimide, composite resin, etc.) containing filler (carbon, oxide, etc.), metal such as Cr and Co, or oxidation Examples thereof include metals, laminated films thereof, porous ceramics, metals, and metal oxides.

  As shown in FIGS. 2 and 3, the lens unit 3 is made of the same material as the substrate 2, a light-transmitting resin, a light-transmitting inorganic / organic hybrid material, or a light-transmitting low-melting-point glass or plastic for replica molding. The hemispherical lens is cut off by two planes substantially orthogonal to the incident surface (bottom surface) 3a and substantially parallel to each other to form a side surface 3b (for example, a curvature radius of 6 to 10 mm, the incident surface 3a The total length of the incident surface 3a (distance between the side surfaces 3b) is 6 to 10 mm, and the height is 5 to 8 mm. It functions as a lens that forms an image on the detector 5b. The lens shape is not limited to a spherical lens, but may be an aspheric lens.

The spectroscopic unit 4 includes a diffraction layer 6 formed on the outer surface of the lens unit 3, a reflection layer 7 formed on the outer surface of the diffraction layer 6, and a reflection layer 8 that covers the diffraction layer 6 and the reflection layer 7. It is a grating. The diffractive layer 6 is formed by arranging a plurality of grating grooves 6 a along the longitudinal direction of the substrate 2, and the extending direction of the grating grooves 6 a substantially coincides with the direction substantially orthogonal to the longitudinal direction of the substrate 2. To do. For the diffraction layer 6, for example, a blazed grating with a sawtooth cross section, a binary grating with a rectangular cross section, a holographic grating with a sinusoidal cross section, etc. are applied, and a photocurable epoxy resin, acrylic resin, or organic-inorganic hybrid resin, etc. This optical resin for replica is formed by photocuring. The reflective layer 7 has a film shape, and is formed by evaporating Al, Au, or the like on the outer surface of the diffraction layer 6, for example. The optical NA of the spectral module 1 can be adjusted by adjusting the area where the reflective layer 7 is formed. It is also possible to integrally form the lens unit 3 and the diffraction layer 6 constituting the spectroscopic unit 4 with the above materials. The passivation layer 8 has a film shape, and is formed, for example, by vapor-depositing MgF ₂ or SiO ₂ on the outer surfaces of the diffraction layer 6 and the reflection layer 7.

  As shown in FIGS. 1, 2 and 4, the light detection element 5 is disposed on the front surface 2a of the substrate 2 and has a rectangular shape (for example, a total length of 5 to 10 mm, a total width of 1.5 to 3 mm, a thickness of 0.1 mm). 1 to 0.8 mm) of a semiconductor substrate 5a (substrate portion). The semiconductor substrate 5a is made of a crystal material such as Si, GaAs, InGaAs, Ge, SiGe.

  A light detection unit 5b is formed on the surface of the semiconductor substrate 5a on the spectroscopic unit 4 side. The light detection unit 5b is a CCD image sensor, a PD array, a CMOS image sensor, or the like, and a direction in which a plurality of channels are substantially orthogonal to the extending direction of the grating grooves 6a of the spectroscopic unit 4 (parallel direction of the grating grooves 6a). It is arranged in. A light shielding layer 12 made of Al, Au, or the like is formed on the surface of the semiconductor substrate 5a opposite to the spectroscopic portion 4 by vapor deposition.

  When the light detection unit 5b is a CCD image sensor, light intensity information at a position incident on a two-dimensionally arranged pixel is line binned to obtain light intensity information at a one-dimensional position. The light intensity information at the one-dimensional position is read out in time series. That is, a line of pixels to be line binned becomes one channel. When the light detection unit 5b is a PD array or a CMOS image sensor, light intensity information at a position incident on a one-dimensionally arranged pixel is read in time series, so that one pixel becomes one channel.

  When the light detection unit 5b is a PD array or a CMOS image sensor and the pixels are two-dimensionally arranged, the pixels lined up in the one-dimensional arrangement direction parallel to the extending direction of the grating grooves 6a of the spectroscopic unit 4 This line becomes one channel. When the light detection unit 5b is a CCD image sensor, for example, the distance between channels in the arrangement direction is 12.5 μm, the total channel length (the length of the one-dimensional pixel row to be line binned) is 1 mm, The number 256 is used for the light detection element 5.

  As shown in FIGS. 2, 4, and 5, the semiconductor substrate 5 a is formed with a light passage hole 50 that is arranged in parallel with the light detection unit 5 b in the channel arrangement direction and through which the light L <b> 1 traveling to the spectroscopic unit 4 passes. Has been. The light passage hole 50 extends in a direction substantially orthogonal to the front surface 2a of the substrate 2 and is formed by etching in a state of being positioned with high accuracy with respect to the light detection portion 5b.

  The light passage hole 50 includes a light incident side 51 that defines a light incident opening 51a through which the light L1 is incident, and a light emission side 52 that defines a light output opening 52a through which the light L1 is emitted. The light incident side portion 51 is formed in a substantially square frustum shape so as to be tapered toward the front surface 2 a of the substrate 2, and has a bottom surface 51 b substantially parallel to the front surface 2 a of the substrate 2.

  The light emitting side portion 52 is formed in a substantially square column shape so as to face and connect to the bottom surface 51b of the light incident side portion 51 from the surface on the spectroscopic portion 4 side of the semiconductor substrate 5a. The side surface 52b is substantially perpendicular to 2a. The light emission side portion 52 has a width H1 (minimum width) that is greater than a width H2 of the slit 13a of the light absorption layer 13 in the channel arrangement direction of the light detection portion 5b (a direction substantially orthogonal to the extending direction of the grating grooves 6a). It is formed to be large.

  An underfill material 15 that transmits at least light L2 is filled between the semiconductor substrate 5a and the substrate 2 or the light absorption layer 13. A rectangular annular convex portion 53 is formed on the surface of the semiconductor substrate 5a on the substrate 2 side so as to surround the light emission opening 52a, and the filled underfill material 15 reaches the light emission opening 52a. It is dammed up by the convex part 53 ahead. This prevents the underfill material 15 from entering the light passage hole 50, so that light can be incident on the main body 2 without being refracted or diffused by the underfill material 15. Further, the external terminal of the light detection element 5 is electrically connected to the pad portion 11 a exposed from the light absorption layer 13 by face-down bonding via the bumps 14. The pad portion 11b is electrically connected to an external electric element (not shown).

  A method for manufacturing the above-described spectral module 1 will be described.

  First, the light detection element 5 is prepared. For example, in the semiconductor substrate 5a made of Si, a rectangular ring is formed so as to surround a light emission opening 52a that is planned by performing alkali etching using KOH (potassium hydroxide), TMAH (tetramethylammonium hydroxide), or the like. The convex portion 53 is formed. Then, the light detection part 5b, wiring, and an electrode pad are prepared in the other main surface B side.

  Subsequently, a mask is opened at a predetermined position by photolithography using double-sided alignment with the detection unit 5b as a reference, and alkali etching is performed to form a light incident side portion 51 having a substantially square frustum shape (FIG. 6). reference). At this time, for example, in the semiconductor substrate 5a made of Si, the side surface 51c of the light incident side 51 along the (111) crystal plane inclined by about 55 ° with respect to the (100) crystal plane by performing alkali etching. Is formed. Then, the bottom surface of the light incident side portion 51 is obtained by performing silicon deep dry etching using plasma discharge at a predetermined position on the other main surface B of the semiconductor substrate 5a by photolithography using the detection portion 5b as a reference. A light emission side portion 52 having a substantially quadrangular prism shape facing 51b is formed (see FIG. 7). In this manner, the light passage hole 50 extending in the direction substantially orthogonal to the one main surface A of the semiconductor substrate 5a is formed. Thereafter, the light shielding layer 12 is formed by vapor-depositing Al, Au, or the like on the one main surface A and the side surface 51c and the bottom surface 51b of the light incident side portion 51, and the wafer is diced on the basis of the detection portion 5b. A photodetecting element 5 is prepared.

Next, the spectroscopic unit 4 is formed in the lens unit 3. Specifically, a light transmissive master grating in which a grating corresponding to the diffraction layer 6 is engraved is pressed against the replica optical resin dropped near the apex of the lens unit 3. Then, the optical resin for replica is cured by irradiating light in this state, and preferably, the diffraction layer 6 having a plurality of grating grooves 6a is formed by performing heat curing for stabilization. Thereafter, the master grating is released, and the reflective layer 7 is formed on the outer surface of the diffractive layer 6 by mask deposition or vapor deposition of Al or Au. Further, the reflective layer 7 is formed on the outer surfaces of the diffractive layer 6 and the reflective layer 7. The passivation layer 8 is formed by depositing MgF ₂ , SiO _2, or the like by mask evaporation or entire surface evaporation.

  On the other hand, the substrate 2 is prepared, and the light absorption layer 13 having the slits 13 a and the openings 13 b is formed on the front surface 2 a of the substrate 2. The slit 13a and the opening 13b are formed so as to have a predetermined positional relationship with respect to the outer edge portion of the substrate 2 serving as a reference portion for positioning the spectroscopic unit 4 on the substrate 2.

  On the light absorption layer 13, the photodetecting element 5 is mounted by face-down bonding. Subsequently, an underfill material 15 is filled between the light detection element 5 and the front surface 2 a of the substrate 2. Thereafter, the spectroscopic module 1 is obtained by adhering the lens unit 3 on which the spectroscopic unit 4 is formed to the rear surface 2b of the substrate 2 with the optical resin agent 18 using the outer edge of the substrate 2 as a reference unit. At this time, the light detecting element 5 and the substrate 2 are electrically connected via the bumps 14.

  The effect of the spectral module 1 mentioned above is demonstrated.

  In the spectroscopic module 1, the light L1 traveling to the spectroscopic portion 4 is formed so as to face the bottom surface 51b of the light incident side portion 51 that is tapered toward the substrate 2 side when passing through the light passage hole 50. Only the light incident on the emission side portion 52 is emitted from the light emission opening 52a. At this time, the stray light M incident on the bottom surface 51b and the side surface 51c of the light incident side portion 51 is reflected to the light incident opening 51a side, so that the stray light can be prevented from entering the light emitting side portion 52. Therefore, the reliability of the spectroscopic module 1 can be improved.

  In the spectroscopic module 1, the light incident side portion 51 is collectively formed by performing alkali etching on the semiconductor substrate 5 a in a wafer state, so that the time required for preparing the light detecting element 5 can be reduced and reduced. Cost can be reduced.

  Further, since the light emission side portion 52 can be formed with high precision by performing silicon deep dry etching from the other main surface B of the semiconductor substrate 5a, the formation of the light passage hole 50 having stable light passage characteristics can be achieved. Thus, the reliability of the spectral module 1 can be improved. Specifically, in the spectroscopic module 1, the light emission side portion 52 is formed from the other main surface B side where the light detection portion 5b is disposed, and thus the light emission side portion 52 with respect to the light detection portion 5b on the same surface. It is possible to increase the position accuracy of the. Since the light passing through the light exit side 52 of the light passage hole 50 is diffracted and reflected by the grating groove 6a of the spectroscopic unit 4 and detected by the light detection unit 5b, the light exit side 52 and the light detection unit By improving the positional accuracy with respect to 5b, it becomes possible to improve the reliability of the spectral module 1. Furthermore, the shape of the opening cross section of the light emission side portion 52 (that is, the shape of the light emission opening 52a) is optically imaged in the light detection portion 5b, and the minimum width of the light emission side portion 52 in the longitudinal direction of the semiconductor substrate 5a. Corresponding to the channels of the light detection section 5b. For this reason, the resolution of the spectroscopic module 1 is greatly affected by the minimum width of the light emitting side portion 52 in the channel arrangement direction. Therefore, by forming the light emission side portion 52 with high precision by performing silicon deep dry etching, it is possible to suppress the variation in resolution for each product and to improve the reliability of the spectral module 1. Become.

  Further, in this spectroscopic module 1, the semiconductor substrate 5a is made of a crystal material such as Si, and the side surface is formed along the (111) crystal plane of the material by performing alkali etching, so that light can be accurately obtained. Since the incident side portion 51 can be formed, the light passing hole 50 can be formed with high accuracy. Therefore, it is possible to improve the reliability of the spectral module 1.

  Further, the resolution of the spectroscopic module 1 is greatly influenced by the minimum width of the slit through which light passes in a direction substantially orthogonal to the extending direction of the grating groove 6a. For this reason, in the direction substantially orthogonal to the extending direction of the grating groove 6a, the spectral module 1 is made by making the width H2 of the slit 13a of the light absorption layer 13 smaller than the minimum width H1 of the light passage hole 50 in the light detection element 5. Resolution can be improved. This is advantageous for improving the reliability of the spectroscopic module 1.

As shown in FIG. 8, the light passage hole 60 formed in the light detection element 5 has a light emitting side portion 62 having a side surface 62 b substantially perpendicular to the bottom surface 61 b of the light incident side portion 61 and an elliptical cross section. It may be formed. Further, as shown in FIG. 9, compared with FIG. 5, the light emission side portion 72 is extended in the direction substantially perpendicular to the longitudinal direction of the semiconductor substrate 5 a (the extending direction of the grating groove 6 a), and the light incident side portion 71 so that the width of the bottom surface 71b of the light emitting side portion 72 is equal to the width of the opening cross section of the light emitting side portion 72, that is, the side surface 72b of the light emitting side portion 72 and the side surface 71c of the light incident side portion 71 are directly connected. May be. Alternatively, as shown in FIG. 10, compared to FIG. 9, the light emission side portion 82 is further extended, and from the width of the bottom surface 81 b of the light incident side portion 81 in the direction substantially orthogonal to the longitudinal direction of the semiconductor substrate 5 a, It may be formed so that the width of the opening cross section of the light emitting side portion 82 becomes longer.
[Second Embodiment]

  The spectroscopic module 21 according to the second embodiment is different from the spectroscopic module 1 according to the first embodiment in the configuration of the light detection element and the point that the wiring board is disposed on the front surface of the substrate.

  As shown in FIGS. 11 and 12, in the spectroscopic module 21, a plurality of terminal electrodes 23 are formed on the surface of the light detection element 22 opposite to the spectroscopic unit 4. Each terminal electrode 23 is connected to the corresponding pad portion 24 a of the wiring substrate 24 by a wire 26. As a result, the terminal electrode 23 and the wiring board 24 are electrically connected, and the electric signal generated in the light detection unit 22b is transmitted to the outside via the terminal electrode 23, the pad part 24a and the pad part 24b of the wiring board 24. It is taken out.

  The light passage hole 90 formed in the semiconductor substrate 22a includes a light incident side portion 91 that defines a light incident opening 91a, and a light emission side portion 92 that defines a light emitting opening 92a. The light incident side portion 91 has a side surface 91 b that is substantially perpendicular to the front surface 2 a of the substrate 2. The light emission side portion 92 is formed in a substantially square frustum shape so as to be widened toward the front surface 2 a of the substrate 2, and has an upper surface 92 b substantially parallel to the front surface 2 a of the substrate 2. The light incident side portion 91 is formed in a substantially quadrangular prism shape so as to face the upper surface 92 b of the light emitting side portion 92, and the side surface 91 b is connected to the upper surface 92 b of the light emitting side portion 92. In addition, the light absorption layer 27 formed on the front surface 2a of the substrate 2 is a slit (light) smaller than the minimum width of the light incident side portion 91 in a direction substantially orthogonal to the extending direction of the grating grooves 6a of the spectroscopic portion 4. Pass slit) 27a.

  The manufacturing method of the manufacturing method of the spectroscopy module 21 mentioned above is demonstrated.

First, the light detection element 22 is prepared. For example, in the semiconductor substrate 22a in a wafer state made of Si, a light detection unit 22b, wiring, and electrode pads are prepared on the other main surface B side. Thereafter, a light shielding layer 29 is formed by vapor-depositing Al, Au, or the like on an insulating film such as SiO _{2 on} the other main surface B, and the light detection element 22 is prepared.

  Subsequently, a rectangular annular convex portion 93 is formed so as to surround a light emission opening 92a that is planned by performing alkali etching or dry etching using KOH (potassium hydroxide) or TMAH (tetramethylammonium hydroxide). Form. Thereafter, a mask is opened at a predetermined position by photolithography using double-sided alignment with respect to one main surface A of the semiconductor substrate 22a with reference to the light detection unit 22b, and KOH (potassium hydroxide) or TMAH ( By performing alkali etching using tetramethylammonium hydroxide, a light emitting side portion 92 having a substantially square frustum shape is formed. Then, the bottom surface of the light emission side portion 92 is obtained by performing silicon deep dry etching using plasma discharge at a predetermined position on the other main surface B of the semiconductor substrate 22a by photolithography using the detection portion 22b as a reference. A light incident side portion 91 having a substantially quadrangular prism shape connected to 92b is formed. In this manner, a light passage hole 90 extending in a direction substantially orthogonal to one main surface A of the semiconductor substrate 22a is formed. Thereafter, the light shielding layer 29 is formed by vapor-depositing Al, Au, or the like on the one main surface A and the side surface 91c and the bottom surface 91b of the light incident side portion 91, and the wafer is diced on the basis of the detection portion 22b. A photodetecting element 22 is prepared.

  Then, the light detection element 22 and the outer edge part of the substrate 2 or the alignment mark are used as a reference part, and the other main surface B side of the light detection element 22 and the optical resin material 17 are bonded to the front surface 2 a of the substrate 2. Thereafter, the terminal electrode 23 of the corresponding light detection element 22 and the pad portion 24 a of the substrate 2 are connected by the wire 26. The pad portion 24 a is electrically connected to the terminal pad portion 24 b through the wiring layer 19. In the substrate 2, since the light absorption layer made of black resist or the like is disposed on the outer periphery of the light detection element 22, it absorbs disturbance light and unnecessary reflected light as a signal from the spectroscopic unit 4, and is reliable. Can be secured.

  Then, the spectroscopic module 21 is obtained by adhering the lens unit 3 on which the spectroscopic unit 4 is formed to the rear surface 2b of the substrate 2 with the optical resin agent 18 using the outer edge of the substrate 2 as a reference unit.

  According to the spectroscopic module 21 according to the second embodiment described above, the light emitting side portion 92 is collectively formed by performing alkali etching on the semiconductor substrate 22a in the wafer state, so that the light detecting element 22 Time reduction and cost reduction in the preparation process can be achieved. Further, since the light emission side portion 52 can be formed with high precision by performing silicon deep dry etching from the other main surface B of the semiconductor substrate 5a, the formation of the light passage hole 50 having stable light passage characteristics can be achieved. Thus, the reliability of the spectral module 1 can be improved.

  The present invention is not limited to the embodiment described above.

  For example, the shapes of the light incident side portion in the first embodiment and the light emission side portion in the second embodiment are not limited to a substantially square frustum shape, and a bottom surface (upper surface) substantially parallel to the front surface 2a of the substrate 2 is used. It may have a shape that has a taper toward the front surface 2a. Similarly, the shape of the light emitting side portion in the first embodiment and the light incident side portion in the second embodiment is not limited to a substantially quadrangular prism shape, and has side surfaces that are substantially perpendicular to the front surface 2a of the substrate 2, In addition, it may be formed so as to face the bottom surface (upper surface) of the paired light incident side portion (light emitting side portion).

  In addition, the light passage hole is not limited to a mode in which the light incident side portion and the light emitting side portion are directly connected to each other, and an intermediate portion (for example, a portion having a different inclination angle of the side surface or shape of the opening cross section) is provided. It may be done.

  Further, the light incident side portion in the first embodiment and the light emission side portion in the second embodiment are not limited to being formed by alkali etching, but may be formed by various wet etching or dry etching. It ’s fine. Similarly, the light emitting side portion in the first embodiment and the light incident side portion in the second embodiment are not limited to being formed by silicon deep dry etching, but may be any form formed by various dry etching. good.

  Further, in the first embodiment described above, the configuration of the light passage hole in the second embodiment may be adopted, and in the second embodiment, the configuration of the light passage hole in the first embodiment is adopted. May be.

  DESCRIPTION OF SYMBOLS 1,21 ... Spectroscopic module, 2 ... Board | substrate (main body part), 2a ... Front surface (predetermined surface), 3 ... Lens part (main body part), 4 ... Spectroscopic part, 5,22 ... Photodetection element, 5a, 22a ... Semiconductor substrate, light detection part ... 5b, 22b, 6 ... diffraction layer, 6a ... grating groove, 13, 27 ... light absorption layer, 50, 60, 70, 80, 90 ... light passage hole, 51, 61, 71, 81 , 91 ... Light incident side, 52, 62, 72, 82, 92 ... Light exit side, 51a, 61a, 71a, 81a, 91a ... Light incident aperture, 51b, 61b, 71b, 81b ... Bottom, 51c, 61c , 71c, 81c, 92c... Side surface, 52a, 62a, 72a, 82a, 92a... Light exit opening, 92b. ... the other main surface.

Claims (1)

A spectroscopic module comprising: a spectroscopic unit that splits and reflects incident light; and a light detection element that detects light split by the spectroscopic unit,
The light detection element has a substrate portion in which a light passage hole through which light traveling to the spectroscopic portion passes is formed,
The light passage hole includes a light incident side portion defining a light incident opening on one main surface of the substrate portion, and a light emitting side portion defining a light emitting opening on the other main surface of the substrate portion,
The light incident side portion has a bottom surface substantially parallel to the one main surface and is formed to be tapered toward the other main surface,
The light emitting side portion has a side surface substantially perpendicular to the other main surface and is formed to face the bottom surface,
A spectroscopic module, wherein a light shielding layer is formed on a side surface of the light incident side portion.

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