JP2017147352A - Semiconductor light receiving element, photoelectric fusion module, method for manufacturing semiconductor light receiving element - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make an effective length of a current flowing in a charge area small while reducing a step between a surface opposite to a substrate in an absorption region and a surface opposite to the substrate in the multiplication region.SOLUTION: A waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed as an avalanche photodiode having a SACM structure in which an absorption region 108 that absorbs the signal light, charge regions 105a, 105b, and a multiplication region 106 are separated. In the waveguide, a charge regions 105a, 105b and the multiplication region 106 are formed adjacent to each other, and the absorption region 108 is laminated on a recess 107 formed in the charge regions 105a, 105b.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a semiconductor light-receiving element, a photoelectric fusion module, and a method for manufacturing a semiconductor light-receiving element. For example, the present invention relates to a semiconductor light-receiving element used in optical fiber communication and a photoelectric fusion module in which an optical circuit and an electric circuit are fused.

  Currently, FTTH (Fiber to the Home) systems, especially PON (Passive Optical Network) systems, which are being introduced, often use single-core bidirectional communication modules that perform bidirectional communication using a single optical fiber. . This single-core bidirectional communication module has been downsized by mounting electronic devices such as LDs (Laser Diodes) and PDs (Photo Diodes) that have been individually mounted on the surface of optical circuit boards. Yes.

The optical circuit employs an optical waveguide using Si as a material. For example, a Si wire waveguide using Si as a core and SiO ₂ having a refractive index much smaller than Si as a cladding is known.
Since the Si fine wire waveguide has a very large refractive index difference between the core and the clad, it is possible to strongly confine light in the core. As a result, the optical device using the Si thin wire waveguide can form a very fine submicron-order waveguide such as a small curved waveguide having a bending radius reduced to about 1 μm. . For this reason, the Si wire waveguide is attracting attention as a technology that has the potential to fuse Si electronic devices and optical devices on the same chip.

  By the way, Non-Patent Document 1 discloses a technique for integrating a waveguide-type PIN structure photodiode (hereinafter also referred to as PIN-PD) in a rib-type waveguide. In this integration technique, a Si core obtained by forming a top Si layer of an SOI (Silicon On Insulator) wafer by a semiconductor process is used as an optical waveguide, and an impurity is added to an end portion through the tapered waveguide, or p-type or n-type A structure with a conductive type is adopted. The PIN-PD is a region having a conductivity type of the Si core, and, for example, Ge is stacked in that region, and an impurity is added to the surface of the stacked Ge so that the conductivity opposite to that of the Si core is achieved. Adopting a structure with a Ge type region (n-type when Si is p-type, p-type when Si is n-type) and an i-type region provided between the p-type region and the n-type region ing.

  Non-Patent Document 2 discloses an avalanche photodiode (hereinafter also referred to as APD) having an integrated SACM structure in which Si waveguides are integrated. Here, the integrated SACM structure refers to a structure in which an absorption region, a charge region, and a multiplication region are separated.

As described above, the integration technology for integrating the SAPD APD in the Si waveguide requires the construction of the SACM structure on the Si slab waveguide by the top Si layer of the SOI substrate. A step between the surface and the surface of the semiconductor layer formed on the surface becomes a problem. In the nonpatent literature 2, this level | step difference is 1.3 micrometers. That is, the thickness of the p-Ge layer (0.1 μm), the thickness of the i-Ge layer (0.5 μm), the thickness of the p ⁺ Si layer (0.1 μm), and the thickness of the i-Si layer (0. 6 μm) is 1.3 μm.

Non-Patent Document 3 discloses an APD having a SACM structure, similar to Non-Patent Document 2. The APD disclosed in Non-Patent Document 3 performs ion implantation on the Si slab waveguide and uses it as a charge region, so that only an absorption region is formed on the Si slab waveguide, and on the Si slab waveguide. The steps are reduced. As a result, in Non-Patent Document 3, the steps on the top Si layer (i-Si layer, p-Si layer) caused by the integration of the light receiving elements are the i-Ge layer thickness of 0.38 μm and the p ⁺ -Ge layer thickness. The sum of 0.12 μm and 0.5 μm. This step is close to the thickness of the top Si layer 220 nm of the SOI wafer.

Tao Yin, et.al, “31GHz Ge n-i-p waveguide structures on Silicone-on-Insulator substrate”, OPTICS EXPRESS, Vol. 15, No. 21, 2007, pp. 13965-13971 Zhihong et.al, “Ge / Si Waveguide Avalanche Photodiodes” IEEE Group Four Photonics, 2010, FA2, p.320,321 Shiyang et.al, “Waveguided Ge / Si Avalanche Photodiode With Separete Vertical SEG-Ge Absorption, Lateral Si Charge, and Multiplication Configuration” IEEE ELECTRON DEVICE LETTERS, VOL.30, No.9, 2009, pp.934-936

  By the way, generally, a mass production factory that integrates Si electronic devices and optical devices demands the highest processing accuracy in the process of processing the top Si layer of an SOI substrate into a Si core. For this reason, the mass production factory often tunes the entire semiconductor process to Si core processing. Therefore, if the level difference of the light receiving element integrated on the Si slab waveguide is about the same as the thickness of the top Si layer of the SOI substrate, for example, 220 nm, integration at a mass production plant is possible, but the level difference exceeding this level Then, the light receiving elements cannot be integrated at the mass production factory. That is, it can be said that the APD disclosed in Non-Patent Document 2 is a light receiving element that cannot be integrated in a mass production factory.

Therefore, a mass production factory that integrates Si electronic devices and optical devices such as optical waveguides may use the technique disclosed in Non-Patent Document 3 in which the level difference is close to the thickness of the top Si layer of the SOI wafer at 220 nm. .
However, the thickness of the charge layer (p-Si layer) is 200 nm for the technique of Non-Patent Document 3 and 100 nm for the technique of Non-Patent Document 2. That is, in the technique of Non-Patent Document 3, the charge layer (charge region) is thicker than the technique of Non-Patent Document 2, so that the current path flowing through the charge region is long. For this reason, the technique of Non-Patent Document 3, for example, 1) takes time for carriers (electrons) generated in the Ge absorption region to diffuse through the charge layer and slows down the operation speed. 2) Charge Since the voltage drop in the layer needs to be taken into consideration, the applied voltage required for multiplication is increased. 3) The probability that carriers will recombine while drifting through the charge layer is increased, so that the desired photosensitivity can be obtained. It has a problem that it is difficult to be formed.

  For this reason, it is necessary to make the current path shorter than the technique of Non-Patent Document 3 while maintaining the thickness of the charge layer at the thickness of the top Si layer of the SOI wafer. By the way, in the technique of Patent Document 3, the path length of the current is longer in the center of the p-Si layer than on both sides. That is, the current path that should be shorter than the technique of Patent Document 3 is the average length (effective length) of the current path of the p-Si layer (charge region).

  The present invention has been made to solve such problems, and reduces the step between the substrate-opposite surface of the absorption region and the substrate-opposite surface of the multiplication region, while reducing the current path in the charge region. An object of the present invention is to provide a semiconductor light receiving element, a photoelectric fusion module, and a method for manufacturing a semiconductor light receiving element that can shorten the effective length of the semiconductor light receiving element.

  In order to achieve the above object, a semiconductor light receiving element according to a first aspect of the present invention is a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed, and an absorption region (108) for absorbing the signal light. ), The charge region (105a), and the multiplication region (106) are separated as an avalanche photodiode having a SACM structure. In the waveguide, the charge region and the multiplication region are adjacent to each other. The absorption region is stacked on a recess (107) formed in the charge region. In addition, the character and code | symbol in () are illustrations (hereinafter the same).

  The recess formed in the charge region reduces the level difference between the surface of the absorption region opposite to the substrate and the surface of the multiplication region opposite to the substrate. Further, the recess forms a charge region (105a) and an insertion region (105b), and the charge region has a shorter current path than the insertion region, so that the effective current path as a whole is shortened.

  A second invention of the present invention is a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed, wherein an absorption region (108) and a charge region (105a) for absorbing the signal light are increased. The amplifying region is formed as an avalanche photodiode having a SACM structure separated from the multiplication region (106). The charge region and the multiplication region are formed adjacent to each other in the waveguide. The region (106) is disposed in a region adjacent to the charge region, further includes an intrinsic semiconductor region (103) formed below the absorption region, and includes the charge region and the intrinsic semiconductor region. A recess (107) is formed in the region, and the absorption region is stacked on the recess.

  According to a third aspect of the present invention, there is provided a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed, the absorption region (108) for absorbing the signal light, and a charge of the first conductivity type. The SACM structure avalanche photodiode in which the region (105a) and the multiplication region (106) are separated from each other is formed, and the charge region and the multiplication region are formed adjacent to each other in the waveguide. The multiplication region (106) is a region adjacent to the charge region and is disposed in a region opposite to the optical axis, and is provided in the other adjacent region of the absorption region. A contact region of one conductivity type (117), and an intrinsic semiconductor region (103) formed below the absorption region; the charge region, the intrinsic semiconductor region, and the first conductivity type contact To the region consisting of regions, are formed recess (107) is, the absorption region (108) is characterized in that it is laminated to the recess.

  According to a fourth aspect of the present invention, both a waveguide-type semiconductor light receiving element formed with a waveguide for receiving signal light and an optical waveguide for guiding the signal light to the waveguide are provided on a support substrate. The photoelectric fusion module is integrally formed, and is formed as an avalanche photodiode having a SACM structure in which an absorption region that absorbs the signal light, a charge region, and a multiplication region are separated. The charge region and the multiplication region are formed adjacent to each other, the absorption region is formed on the surface of a recess formed adjacent to the charge region, and the optical waveguide has a core formed by the core It is characterized by being integrally formed with the multiplication region.

  According to a fifth aspect of the present invention, there is provided a method for manufacturing a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed on an SOI substrate, wherein the semiconductor light receiving element absorbs the signal light. A SACM-structured avalanche photodiode in which a region, a charge region, and a multiplication region are separated, and a multiplication region disposed in the optical waveguide, the charge region, and a region adjacent to the charge region A Si layer forming process for forming the Si layer of the SOI substrate, a recess forming process for forming a recess adjacent to the charge region, and an absorption region growing process for growing a Ge absorption region in the recess; It is characterized by providing.

  According to the present invention, the effective length of the current flowing in the charge region can be shortened while reducing the level difference between the surface of the absorption region opposite to the substrate and the surface of the multiplication region opposite to the substrate.

It is sectional drawing which shows a cross section perpendicular | vertical with respect to the optical axis of the semiconductor light receiving element which is 1st Embodiment of this invention. 1 is a plan view of a semiconductor light receiving element according to a first embodiment of the present invention. It is sectional drawing for demonstrating operation | movement of the semiconductor light receiving element which is 1st Embodiment of this invention. It is a figure which shows the relationship between the distance from an optical axis, and electric field strength with respect to the direction perpendicular | vertical to an optical axis and parallel to a board | substrate. It is a flowchart for demonstrating the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (1) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (2) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (3) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (4) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (5) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (6) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (7) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (8) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (9) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is explanatory drawing (10) explaining the manufacturing method of the semiconductor light receiving element which is 1st Embodiment of this invention. It is sectional drawing which shows a cross section perpendicular | vertical with respect to the optical axis of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is sectional drawing for demonstrating operation | movement of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is a figure which shows the relationship between the distance from an optical axis, and electric field strength with respect to the direction perpendicular | vertical to an optical axis and parallel to a board | substrate. It is explanatory drawing (1) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (2) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (3) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (4) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (5) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (6) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (7) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (8) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (9) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is explanatory drawing (10) explaining the manufacturing method of the semiconductor light receiving element which is 2nd Embodiment of this invention. It is a block diagram of the photoelectric fusion module to which the semiconductor light receiving element which is 1st Embodiment of this invention is applied. It is sectional drawing which shows a cross section perpendicular | vertical with respect to the optical axis of the semiconductor light receiving element which is a modification of this invention.

  Hereinafter, an embodiment of the present invention (hereinafter referred to as “the present embodiment”) will be described in detail with reference to the drawings. Each figure is only schematically shown so that the present invention can be fully understood. Moreover, in each figure, the same code | symbol is attached | subjected about the common component and the same component, and those overlapping description is abbreviate | omitted.

(First embodiment)
(Description of configuration)
FIG. 1 is a cross-sectional view showing a cross section perpendicular to the optical axis of the semiconductor light receiving element according to the first embodiment of the present invention, and FIG. 2 is a plan view thereof. That is, FIG. 1 is an xy cross-sectional view when the z-axis is set to the light traveling direction (see FIG. 2). FIG. 2 is an xz plan view as seen from the p-Ge contact region 109.

  The semiconductor light receiving element 100 includes an Si substrate 101 as a support substrate, a lower clad 102 deposited on the surface of the Si substrate 101, an Si slab waveguide 103 formed on the surface of the lower clad 102, and an n-Si contact. The region 104, the p-Si region 105 (p-Si charge region 105 a and insertion region 105 b) forming the recess 107, the non-doped multiplication region 106, and the i-Ge absorption region 108 stacked on the recess 107. A p-Ge contact region 109 formed on the upper side of the i-Ge absorption region 108 on the opposite side of the substrate, an upper clad 111 covering them, and two Al electrodes 110a in contact with the n-Si contact region 104, and an Al electrode 110b in contact with the p-Ge contact region 109. Note that the insertion region 105 b of the p-Si region 105 means a region interposed between the lower clad 102 and the i-Ge absorption region 108.

  In FIG. 2, the Si slab waveguide 103, the multiplication region 106, the Si fine wire waveguide 115, and the taper waveguide 116 are integrally formed of the same Si layer. Therefore, the boundary between the Si wire waveguide 115 and the taper waveguide 116, the boundary between the taper waveguide 116 and the Si slab waveguide 103, and the boundary between the Si slab waveguide 103 and the multiplication region 106 are indicated by broken lines. ing.

  The Si slab waveguide 103 has a rectangular shape in plan view, and the light is guided in the optical axis direction together with the two multiplication regions 106, the p-Si region 105, and the like arranged in parallel to the optical axis. A waved waveguide is formed. That is, the semiconductor light receiving element 100 functions as a waveguide type avalanche photodiode.

  The tapered waveguide 116 is an optical waveguide that is coupled to the p-Si region 105 (p-Si charge region 105a) via the Si slab waveguide 103 and guides signal light to the p-Si region 105. . The i-Ge absorption region 108 passes through the optical axis, and the n-Si contact region 104, the p-Si region 105, the non-doped multiplication region 106, the Al electrode 110a, and the like are on both sides of the i-Ge absorption region 108. Are arranged parallel to the optical axis.

Returning to the description of FIG. 1, the Si substrate 101 is, for example, a support substrate having a thickness t ₁ = 525 μm. The lower clad 102 is, for example, SiO ₂ having a thickness t ₂ = 3 μm, and is an insulating layer deposited on the entire surface of the Si substrate 101. The Si slab waveguide 103 is, for example, Si having a thickness t ₃ = 300 nm. The Si slab waveguide 103 is formed in the optical axis direction (z direction), and in the cross-sectional view of FIG.

The n-Si contact region 104 is a region having the same depth t ₃ = 300 nm as that of the Si slab waveguide 103. For example, P (phosphorus) is ion-implanted at a carrier concentration of 1 × 10 ²⁰ cm ⁻³ . In the p-Si region 105, for example, B (boron) is ion-implanted at a carrier concentration of 1 × 10 ¹⁷ cm ⁻³ . That is, the p-Si region 105 has a lower carrier concentration and lower conductivity than the n-Si contact region 104. In the p-Si region 105, for example, a recess 107 is formed at a depth (t ₃ -t ₆ ) = 250 nm. When the recess 107 is distinguished by the side surface 107a and the bottom surface 107b, the p-Si region 105 is distinguished into a p-Si charge region 105a on both sides in the x direction and an insertion region 105b having a thickness t ₆ = 50 nm. Here, the insertion region 105 b is a Si layer that is highly necessary for epitaxial growth of the i-Ge absorption region 108.

The multiplication region 106 is non-doped Si (i-Si), and is formed between the n-Si contact region 104 and the p-Si charge region 105a. The i-Ge absorption region 108 is formed on the recess 107 with a thickness t ₇ = 0.5 μm, for example. The p-Ge contact region 109 is formed on the i-Ge absorption region 108 with a depth t ₈ = 0.16 μm and a carrier concentration of 1 × 10 ²⁰ cm ⁻³ , for example.

The Al electrode 110a is formed on the n-Si contact region 104 with a thickness t ₄ = 1 μm, for example, and the Al electrode 110b is formed on the p-Ge contact region 109 with a thickness t ₄ = 1 μm, for example. It is formed with.

The upper clad 111 is made of SiO ₂ having a thickness t ₉ = 1 μm, covers the Si slab waveguide 103 and the i-Ge absorption region 108, and is formed so that the Al electrodes 110a and 111b are exposed.

(Description of operation)
FIG. 3 is a cross-sectional view for explaining the operation of the semiconductor light receiving element according to the first embodiment of the present invention. In particular, FIG. 3A is a yz cross-sectional view parallel to the optical axis. FIG. 3B is an xy cross-sectional view perpendicular to the optical axis.
The semiconductor light receiving element 100 of this embodiment has substantially the same operating principle as the waveguide type avalanche photodiode having the SACM structure.

  First, as shown in FIG. 3A, the signal light propagating through the Si thin wire waveguide 115 and the Si slab waveguide 103 is refracted in the p-Si charge region 105a and is batted into the i-Ge absorption region 108. Coupling and propagating through the i-Ge absorption region 108. Note that the insertion region 105b of the p-Si region 105 has a long length, so that a current is less likely to flow than the p-Si charge region 105a. That is, the current path through which electrons flow is limited to the p-Si charge region 105a. In the technique of Non-Patent Document 3 in which the recess 107 is not formed, the current concentrates on the i-Si layer side on both sides of the p-Si layer, and the current density in the central portion is reduced. That is, in the technique of Non-Patent Document 3, the center length of the p-Si layer has a longer current path length than both sides, and the average length (effective length) of the current path in the p-Si layer (charge region) is larger. It is longer than the p-Si region 105 of this embodiment. In other words, the substantial thickness of the p-Si region 105 (p-Si charge region 105a) of the present embodiment is thinner than that of the technique of Non-Patent Document 3.

  Next, as illustrated in FIG. 3B, the i-Ge absorption region 108 absorbs signal light, and the absorbed signal light generates electrons and holes that are carriers. At this time, when the DC power supply E applies a reverse bias (positive on the n-Si contact region 104 side and negative on the p-Ge contact region 109 side), electrons drift in the direction of the n-Si contact region 104, as shown in FIG. Then, the holes drift in the direction of the p-Ge contact region 109 according to the electric field inside the i-Ge absorption region 108. That is, electrons generated in the i-Ge absorption region 108 flow to the n-Si contact region 104 through the p-Si charge region 105 a and the multiplication region 106.

FIG. 4 is a diagram showing the relationship between the distance from the optical axis and the electric field strength with respect to the direction perpendicular to the optical axis and parallel to the substrate.
The semiconductor light receiving element 100 of the present embodiment has a SACM structure and the p-Si charge region 105a exists, so that the internal electric field of the i-Ge absorption region 108 can be suppressed low. Here, since the n-Si contact region 104 has high conductivity, the electric field strength is almost zero. However, since the p-Si charge region 105a has low carrier density and low conductivity, the electric field strength is x. It gradually changes to zero according to the direction distance.

  In the semiconductor light receiving element 100, since the internal electric field of the i-Ge absorption region 108 is low, even if the reverse bias is increased, the electric field is mainly applied to the i-Si multiplication region 106, and the i-Ge absorption region 108 increases. There is a feature that is difficult to double and hard to break.

  Then, the electrons generated in the i-Ge absorption region 108 drift through the p-Si charge region 105 a and reach the i-Si multiplication region 106. The drift of the electrons that have reached the i-Si multiplication region 106 is accelerated by the high internal electric field of the i-Si multiplication region 106, which causes avalanche multiplication and generates a large number of electrons.

  The electrons multiplied in the i-Si multiplication region 106 drift as they are, reach the n-Si contact region 104, and are output to the external circuit as a generated current through the Al electrode 110a. On the other hand, holes generated in the i-Ge absorption region 108 drift due to the internal electric field of the i-Ge absorption region 108, reach the p-Ge contact region 109, and are output to the external circuit as generated current through the Al electrode 110b. Is done.

  Si has an intrinsic carrier concentration lower than that of Ge and has a high resistivity. For this reason, in the avalanche photodiode, it is more efficient to apply a higher electric field when Si is used for the multiplication region and Ge is used for the absorption region. Also, depending on the semiconductor material, there is a unique value for the multiplication factor of each carrier. For example, since Si has an electron multiplication factor about 10 times larger than that of holes, the avalanche photodiode is made p-type on the Ge side and n-type on the Si side so that the i-Si multiplication region can multiply electrons. Is efficient.

(Comparison between PIN-PD and APD)
Here, PIN-PD and APD (especially APD of SACM structure) are compared.
The light receiving sensitivity R of PIN-PD (a value [A / W] obtained by dividing the generated current Iph by the input optical power Pin to PD [A / W]) is generally an electron elementary quantity e [C], an external quantum efficiency η, a Planck constant. Is h [m ² kg / s], and the light frequency is ν [/ s].
R = eη / hν
From the above equation, when receiving light with a wavelength of 1490 nm, even if the external quantum efficiency can be increased to 1 in the ideal state, the light receiving sensitivity is about 1.2 [A / W] at the upper limit in PIN-PD. is there.

  The APD is a semiconductor light receiving element that can obtain higher light receiving sensitivity than PIN-PD by utilizing the avalanche breakdown phenomenon of a diode. Even with PIN-PD, avalanche multiplication occurs in the light absorption region by increasing the bias. Therefore, in Ge-PD, a high electric field is applied to the i-Ge layer, and avalanche multiplication occurs in the i-Ge layer. However, Ge has a low withstand voltage and causes dielectric breakdown in an electric field lower than that of Si. In order to suppress this breakdown, a SAM (Separeted Absorption and Multiplication Layer) structure has been developed. This SAM structure is a structure in which a light absorption region and a multiplication region are separated. By using Si for the multiplication region, a high electric field can be applied to Si having a higher resistance than Ge. Can be suppressed.

  However, in the SAM structure, when an electric field sufficient to obtain a highly efficient avalanche multiplication with Si is applied, a considerably high electric field is also applied to Ge, and there remains a problem that Ge is easily broken down. Yes. In order to solve this problem, the SACM structure has been developed. In the SACM structure, a charge region (for example, p-Si for p-Ge) having the same polarity as the contact region of the light absorption region is provided between the light absorption region and the multiplication region. With the SACM structure, it is possible to obtain a highly efficient avalanche multiplication with Si while suppressing the application of a high electric field to the light absorption region in the charge region and suppressing the dielectric breakdown of Ge.

(Description of manufacturing method)
FIG. 5 is a flowchart for explaining the method of manufacturing the semiconductor light receiving element according to the first embodiment of the present invention.
The manufacturer or the manufacturing apparatus first prepares an SOI substrate (S1), forms a Si slab waveguide (S3), forms an n-Si contact region (S5), and forms an n-Si charge region (S5). S7). Next, the manufacturer or the manufacturing apparatus forms a recess in the top Si layer of the formed SOI substrate (S9), and selectively grows an i-Ge absorption region (S11). Next, the manufacturer or the manufacturing apparatus forms a p-Ge contact region (S13), deposits an upper cladding layer (S15), forms a contact hole (S17), and then forms a contact Al electrode on the p-Ge contact region. (S19).

6A to 6J are process diagrams for explaining an example of the manufacturing method of the semiconductor light receiving element of the first embodiment. The semiconductor light receiving element 100 can be formed by a normal semiconductor manufacturing process.
First, a manufacturer or a manufacturing apparatus prepares an SOI substrate 113 in which a lower clad 102 made of SiO ₂ and a top Si layer 112 are laminated on the surface of a Si substrate 101 (FIG. 6A, S1). Next, the top Si layer 112 is patterned on the SOI substrate 113 by photolithography and dry etching to form the Si slab waveguide 103 (FIG. 6B, S3).

  Next, using a resist mask by photolithography, for example, P (phosphorus) ions are partially implanted into the Si slab waveguide 103 to form two n-Si contact regions 104 (FIG. 6C, S5). ).

  Next, the manufacturer or the manufacturing apparatus uses the photolithography resist mask to form the multiplication region 106 between the n-Si contact regions 104 partially formed in two places in the Si slab waveguide 103. The p-Si region 105 is formed by implanting, for example, B (boron) ions at intervals so as to be formed (FIG. 6D, S7).

Next, the manufacturer or the manufacturing apparatus patterns the p-Si region 105 by photolithography and dry etching to form a recess 107 having a tapered side surface (FIG. 6E, S9). The dry etching of the p-Si region 105 at this time uses, for example, a SiO ₂ film as a hard mask in view of Ge selective growth in the next step.

Next, the manufacturer or the manufacturing apparatus selectively grows the i-Ge absorption region 108 on the recess 107 (FIG. 6F, S11). At this time, the hard mask (for example, SiO ₂ film) in the previous process acts as a selective mask for Ge growth, and Ge can be grown only in the recess. Next, the manufacturer or the manufacturing apparatus partially implants, for example, B (boron) into the upper surface of the i-Ge absorption region 108 using a resist mask by photolithography, and the thickness t ₈ = 0. A 16 μm p-Ge contact region 109 is formed (FIG. 6G, S13).

Next, the manufacturer or the manufacturing apparatus deposits, for example, a SiO ₂ film to a thickness t ₉ = 1 μm by chemical vapor deposition to form the upper clad 111 (FIG. 6H, S15). Next, the manufacturer or the manufacturing apparatus patterns the upper clad 111 by photolithography and dry etching to form a contact hole 114 on the n-Si contact region 104 and the p-Ge contact region 109 (FIG. 6I). , S17).

Finally, the manufacturer or the manufacturing apparatus forms an Al film by sputtering so as to cover the contact hole 114, and performs patterning by photolithography and dry etching to obtain Al electrodes 110a and 110b having a thickness t ₄ = 1 μm. Thus, the semiconductor light receiving element 100 of the present embodiment is manufactured (FIG. 6J, S19).

(Explanation of effect)
As described above, in the semiconductor light receiving element 100 (waveguide type avalanche photodiode having the SACM structure) of this embodiment, the recess 107 is formed in the p-Si region 105, and the i-Ge absorption region is formed in the recess 107. 108 is formed. With this formation, the step t ₉ (FIG. 1) between the upper surface of the Si slab waveguide 103 obtained by processing the top Si layer 112 (FIG. 6A) of the SOI substrate 113 and the upper surface of the i-Ge absorption region 108 is (i− The thickness t ₇ of the Ge absorption region 108 is 0.5 μm) − {the depth of the recess 107 (t ₃ −t ₆ ) = 250 nm} = 250 nm. This step t ₉ is smaller than the thickness t ₃ = 300 nm of the top Si layer 112 of the SOI substrate 113. For this reason, the mass production facility can easily integrate the Si electronic device and the optical device such as the waveguide even if the entire semiconductor process is tuned to the Si core processing.

In the semiconductor light receiving element 100, by forming the recess 107 in the p-Si region 105, electrons flow in the p-Si charge region 105a. That is, since the semiconductor light receiving element 100 can effectively reduce the width of the p-Si charge region 105a, the above-described plurality of problems can be solved. That is, the semiconductor light receiving element 100 is
1. Since carriers generated in the Ge absorption region drift and pass through the p-Si charge region 105a, it does not take time to pass and the operation speed is increased. That is, since carriers (electrons) flow to the p-Si charge region 105a, an effective current path is short.
2. Since the voltage drop in the p-Si charge region 105a is small, the applied voltage required for multiplication can be kept low.
3. Since the recombination probability is low while carriers (electrons) drift in the p-Si charge region 105a, it is easy to obtain a desired light receiving sensitivity.

(Second Embodiment)
The semiconductor light receiving element 100 according to the first embodiment is a vertical device that allows a current to flow in the vertical direction with respect to the Si substrate 101. Thus, it can be configured as a lateral device that allows current to flow in a vertical direction.
(Description of configuration)
FIG. 7 is a cross-sectional view perpendicular to the optical axis of the semiconductor light receiving element according to the second embodiment of the present invention. That is, FIG. 7 is an xy sectional view when the direction of the signal light is the z direction.

  The semiconductor light receiving element 150 of this embodiment is not a vertical structure of the semiconductor light receiving element 100 of the first embodiment but a horizontal structure, and a reverse bias is applied to the two Al electrodes 110a and 110a.

Compared with the semiconductor light receiving element 100 of the first embodiment, the semiconductor light receiving element 150 does not have a contact region and an Al electrode above the i-Ge absorption region 108. The semiconductor light receiving element 100 has the n-Si contact regions 104 on both sides. However, one of the semiconductor light receiving elements 150 is the n-Si contact region 104 but the other is the p-Si contact region 117. Is different. The p-Si contact region 117 has a carrier concentration of, for example, 1 × 10 ²⁰ cm ⁻³ and is common to the n-Si contact region 104. That is, the n-Si contact region 104 is formed on one side of the i-Ge absorption region 108 via the multiplication region 106 in a cross-sectional view perpendicular to the optical axis, and the p-Si contact region 117 is formed on the other side surface.

  Further, the p-Si region 105 of the semiconductor light receiving element 100 is distinguished by the recess 107 into the p-Si charge region 105 a and the insertion region 105 b, but the semiconductor light receiving element 150 is interposed between the p-Si region 105. The difference is that a Si slab waveguide 103 is formed instead of the insertion region 105b. That is, the p-Si charge region 105 a is formed in an L shape in a cross-sectional view perpendicular to the optical axis, and is provided only on one side of the i-Ge absorption region 108.

  The multiplication region 106 is a region adjacent to the p-Si charge region 105a, and is formed in a region opposite to the absorption region 108 and the optical axis. The recess 107 is formed for the p-Si charge region 105a, the Si slab waveguide 103, and the p-Si contact region 117. Note that the Si slab waveguide 103 is formed of i-Si (intrinsic semiconductor), which is the same as the tapered waveguide 116.

(Description of operation)
FIG. 8 is a cross-sectional view for explaining the operation of the semiconductor light receiving element according to the second embodiment of the present invention. FIG. 8A is a cross-sectional view parallel to the optical axis, and FIG. These are sectional views showing a plane perpendicular to the optical axis.
The semiconductor light receiving element 150 of the present embodiment has the same operation principle as that of a waveguide type avalanche photodiode having a SACM structure. As shown in FIG. 8A, the signal light that has propagated through the Si wire waveguide 115 and the Si slab waveguide 103 is butt-coupled to the i-Ge absorption region 108 and propagates through the i-Ge absorption region 108. To do. In addition, since the Al electrode 110b does not exist on the i-Ge absorption region 108, the semiconductor light receiving element 150 of this embodiment does not scatter or absorb propagating light due to metal loading. For this reason, the semiconductor light receiving element 150 can propagate through the i-Ge absorption region 108 with low loss.

  Next, as illustrated in FIG. 8B, the i-Ge absorption region 108 absorbs signal light and generates electrons and holes that are carriers. At this time, since the p-Ge contact region 109 does not exist on the surface opposite to the substrate of the i-Ge absorption region 108 in the semiconductor light-receiving device 150 of this embodiment, the semiconductor light-receiving device 150 has carriers generated by the p-Ge contact region 109. There is a merit that non-occurrence (light absorption) does not occur.

  Further, when Ge is selectively grown by the same thickness, the semiconductor light receiving element 150 of the present embodiment is more efficient because the i-Ge absorption region 108 is formed thicker than the semiconductor light receiving element 100 of the first embodiment. Can generate a carrier. In other words, the semiconductor light receiving element 150 has an advantage that Ge can be selectively grown to be thinner than the semiconductor light receiving element 100 of the first embodiment to reduce the influence of the step due to the light receiving element integration.

  8B, when the DC power source E applies a reverse bias (positive on the n-Si contact region 104 side and negative on the p-Si contact region 117 side), electrons move in the direction of the n-Si contact region 104. The holes drift in the direction of the p-Si contact region 117 along the electric field inside the i-Ge absorption region 108. That is, electrons flow from the p-Si contact region 117 to the n-Si contact region 104 through the i-Ge absorption region 108, the p-Si charge region 105a, and the multiplication region 106.

FIG. 9 is a diagram showing the relationship between the distance from the optical axis and the electric field strength with respect to the direction perpendicular to the optical axis and parallel to the Si substrate.
Since the semiconductor light receiving element 150 has a SACM structure and the p-Si charge region 105a exists, the electric field inside the i-Ge absorption region 108 can be suppressed low. For this reason, even if the bias voltage is increased, the electric field is mainly applied to the i-Si multiplication region 106 in the semiconductor light-receiving element 150. There are difficult features.

  Then, the electrons generated in the i-Ge absorption region 108 drift through the p-Si charge region 105 a and reach the i-Si multiplication region 106. The drift of the electrons that have reached the i-Si multiplication region 106 is accelerated by a high electric field inside the i-Si multiplication region 106, whereby avalanche multiplication occurs and a large number of electrons are generated. The electrons multiplied in the i-Si multiplication region 106 drift as they are to reach the n-Si contact region 104, and are output to the external circuit as a generated current through the Al electrode 110a. On the other hand, holes generated in the i-Ge absorption region 108 drift by the electric field inside the i-Ge absorption region 108, reach the p-Si contact region 201, and are output to the external circuit as generated current through the Al electrode 110a. Is done.

(Production method)
FIGS. 10A to 10J are explanatory views (1) for explaining the method of manufacturing the semiconductor light receiving element according to the second embodiment of the present invention.
The semiconductor light receiving element 150 of the present embodiment can be formed by a normal semiconductor manufacturing process.
First, a manufacturer or a manufacturing apparatus prepares an SOI substrate 113 in which a lower clad 102 made of SiO ₂ and a top Si layer 112 are laminated on the surface of a Si substrate 101 (FIG. 10A).
Next, the top Si layer 112 is patterned on the SOI substrate 113 by photolithography and dry etching to form the Si slab waveguide 103 (FIG. 10B).
Next, using a resist mask by photolithography, for example, P (phosphorus) is ion-implanted partially into the Si slab waveguide 103 to form one n-Si contact region 104 (FIG. 10C).

  Next, the manufacturer or the manufacturing apparatus uses the resist mask by photolithography so that the multiplication region 106 is partially formed in the Si slab waveguide 103 and between the n-Si contact region 104. A p-Si region 105 is formed by implanting, for example, B (boron) ions at intervals (FIG. 10D). At this time, the manufacturer or the manufacturing apparatus forms the p-Si region 105 so that one end side of the recess formed in the Si slab waveguide 103 in the next process overlaps.

  Next, the manufacturer or the manufacturing apparatus forms a p-Si contact region 117 by partially implanting, for example, B (boron) into the Si slab waveguide 103 using a resist mask by photolithography. FIG. 10E). At this time, the manufacturer or the manufacturing apparatus forms the p-Si contact region 117 so that the other end side of the recess overlaps the p-Si contact region 117.

Next, the manufacturer or the manufacturing apparatus patterns the p-Si charge region 105a, the Si slab waveguide 103, and the p-Si contact region 117 by photolithography and dry etching to form the recess 107 (FIG. 10F). In this case, dry etching of the p-Si charge region 105a, the Si slab waveguide 103, and the p-Si contact region 117 uses, for example, a SiO ₂ film as a hard mask in view of the Ge selective growth in the next step. Next, the manufacturer or the manufacturing apparatus selectively grows the i-Ge absorption region 108 on the surface of the recess 107 (FIG. 10G). At this time, since the hard mask (for example, SiO ₂ film) in the previous process acts as a selective mask for Ge growth, the manufacturer or the manufacturing apparatus can grow Ge only in the recess 107.

Next, the manufacturer or the manufacturing apparatus forms, for example, an SiO ₂ film by chemical vapor deposition to form the upper clad 111 (FIG. 10H). Next, the manufacturer or the manufacturing apparatus patterns the upper clad 111 by photolithography and dry etching to form a contact hole 114 on the surface of the n-Si contact region 104 and the p-Si contact region 201 (FIG. 10I). Finally, the manufacturer or the manufacturing apparatus forms an Al film by sputtering so as to cover the contact hole 114, and performs patterning by photolithography and dry etching to form the Al electrode 110a (FIG. 10J). Through these steps, the semiconductor light receiving element 150 is formed.

(Explanation of effect)
As described above, the semiconductor light receiving element 150 of the present embodiment can obtain the same effects as the semiconductor light receiving element 100 of the first embodiment, and also the Al electrode 110b on the i-Ge absorption region 108 (FIG. 1). Scattering and absorption of propagating light due to metal loading caused by For this reason, the semiconductor light receiving element 150 can propagate the i-Ge absorption region with low loss of signal light, and can obtain more efficient light receiving sensitivity.

  Furthermore, since the p-Ge contact region does not exist on the upper surface of the i-Ge absorption region, the semiconductor light receiving element 150 does not absorb light that does not generate carriers due to the p-Ge contact region. Further, when Ge is selectively grown by the same thickness, the semiconductor light receiving element 150 can efficiently generate carriers because the i-Ge absorption region 108 is formed thicker than the semiconductor light receiving element 100. Further, since the semiconductor light receiving element 150 is thinner than the semiconductor light receiving element 100 and can selectively grow Ge, it is possible to reduce the influence of the step due to the integration of the light receiving elements in the manufacturing process.

(Photoelectric fusion module)
FIG. 11 is a configuration diagram of a photoelectric fusion module to which the semiconductor light receiving element according to the first embodiment of the present invention is applied.
The optoelectronic module 200 is, for example, a single-core bidirectional communication module used in a PON system, and an optical circuit 210 and an electric circuit 220 are formed on the surface of the lower clad 102 stacked on the Si substrate 101. . Here, the optical circuit 210 is composed of a spot size converter 211 and a wavelength multiplexer / demultiplexer 212, and the wavelength multiplexer / demultiplexer 212 is composed of a Si fine wire waveguide 115 as an optical waveguide. The electric circuit 220 includes the semiconductor light receiving element 100, a laser diode 222 as a semiconductor light emitting element, a transimpedance amplifier 221, and a monitoring photodiode 223. That is, the optoelectronic module 200 has a configuration in which the Si thin wire waveguide 115 and the semiconductor light receiving element 100 are coupled, and the optical circuit 210 and the electric circuit 220 are integrated.

  The wavelength multiplexer / demultiplexer 212 guides the signal light emitted from the laser diode 222 to the spot size converter 211, and causes the signal light guided from the spot size converter 211 to enter the semiconductor light receiving element 100. It includes a waveguide 116 (FIG. 2). In addition, since bidirectional communication is performed using a single optical fiber, the wavelength of light incident on the photodiode 222 should be cut off from the wavelength of light emitted by the laser diode provided at the other end of the optical fiber. ing. For example, when the transmission wavelength of the laser diode 222 is 1.310 nm and the reception wavelength of the semiconductor light receiving element 100 is 1.49 nm, the wavelength of light incident on the semiconductor light receiving element 100 is provided at the other end of the optical fiber. The wavelength of light emitted by the laser diode is 1.310 nm. The Si wire waveguide 115 is an optical waveguide having a core material made of silicon and a clad material made of quartz, and the light path can be bent more sharply than a conventionally used quartz optical waveguide.

  The spot size converter 211 is for coupling between an optical fiber (not shown) and a silicon fine wire waveguide, and uses a tapered taper type. That is, the spot size converter 211 has a function of converting the size of the light beam spot, and is provided to reduce the optical power loss in the light input / output. A taper type spot size conversion is used between the laser diode 222 and the waveguide, and a grating type is used between the semiconductor light receiving element 100 and the waveguide.

The transimpedance amplifier 221 converts the current generated by the semiconductor light receiving element 100 into a voltage while virtually grounding the voltage across the semiconductor light receiving element 100.
The monitoring photodiode 223 is for monitoring the optical output of the laser diode 222 and performing feedback control, and is disposed in proximity to the laser diode 222.

(Modification)
The present invention is not limited to the embodiments described above, and various modifications such as the following are possible.
(1) The semiconductor light receiving element 100 according to the first embodiment includes a p-Ge contact region 109 / i-Ge absorption region 108 / p-Si charge region 105a / i-Si multiplication region 106 / n-Si contact region 104. It is the composition. This configuration is adopted because Si has a lower intrinsic carrier concentration than Ge and has a higher resistivity, so using Si for the multiplication region and using Ge for the absorption region can apply a higher electric field. Yes. Further, it is known that the multiplication factor of Si is about 10 times higher than that of holes, and the Ge side is made p-type so that the i-Si multiplication region can multiply electrons. This is because the side is n-type. In other words, it is possible to use Si for the absorption region and Ge for the multiplication region. It is also possible to exchange the p-type and n-type conductivity types. Also, the charge layer can be n-type.

(2) The Al electrodes are used for the semiconductor light receiving elements 100 and 150 of the above embodiments, but the present invention is not limited to this as long as it is a metal material that can form ohmic contact with Si or Ge. For example, Cu is also possible. In the semiconductor light receiving elements 100 and 150, SiO ₂ is used as the upper clad material. For example, SiON can be used.

(3) The semiconductor light receiving elements 100 and 150 of each of the embodiments described above have a configuration and manufacturing method in which a Ge layer is present directly on the Si layer, but a buffer such as a SiGe layer is provided between the Si layer and the Ge layer. A layer may be interposed. Similarly, a protective layer such as a Si layer may be provided on the Ge layer.

(4) Although the semiconductor light receiving elements 100 and 150 of the above embodiments have been described with respect to the Ge layer selective growth on the Si layer, the combination of materials is not limited thereto. For example, in addition to SiGe mixed crystal layer selective growth on the Si layer, materials that can be selectively grown on the base material can be combined.

(5) In the recess 107 of each of the embodiments, the side surface 107a is tapered and the recess is formed, but it may be perpendicular to the bottom surface.

(6) In the semiconductor light receiving element 100 of the first embodiment, the recess 107 is formed in the p-Si region 105. As shown in FIG. 12, the cross section is provided at two locations adjacent to both end faces of the recess 107. An L-shaped p-Si charge region 105a may be provided. That is, in the semiconductor light receiving element 160, the Si slab waveguide 103 is thinly provided below the i-Ge absorption region 108, and the p-Si charge region 105a on both sides and the region where the Si slab waveguide 103 is configured, A recess 107 is formed.

(7) In each of the embodiments and the semiconductor light receiving elements 100, 150, and 160 of the modification (6), the insertion region 105b of the p-Si region 105 is provided below the i-Ge absorption region 108, The Si slab waveguide 103 is thinly provided. The i-Ge absorption region 108 may be grown on the surface of the lower clad 102 opposite to the substrate without providing the insertion region 105b or the Si slab waveguide 103. In other words, the i-Ge absorption region 108 is stacked in a region adjacent to the p-Si charge region 105a.

100, 150, 160 Semiconductor light receiving element 101 Si substrate (support substrate)
102 Lower clad 103 Si slab waveguide (intrinsic semiconductor region)
104 n-Si contact region 105 p-Si region 105a p-Si charge region 105b insertion region 106 multiplication region 107 recess 107a side surface 107b bottom surface 108 i-Ge absorption region 109 p-Ge contact region 110a, 110b Al electrode 111 upper part Clad 112 Top Si layer 113 SOI substrate 114 Contact hole 115 Si wire waveguide (optical waveguide)
116 Tapered waveguide (optical waveguide)
117 p-Si contact region 200 photoelectric fusion module 210 optical circuit 211 spot size converter 212 wavelength multiplexer / demultiplexer 220 electric circuit 221 transimpedance amplifier 222 laser diode 223 monitoring photodiode E DC power supply

In order to achieve the above object, a semiconductor light receiving element according to a first aspect of the present invention is a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed, and an absorption region (108) for absorbing the signal light. ), The charge region (105a), and the multiplication region (106) are separated as an avalanche photodiode having a SACM structure, and the charge region and the multiplication region are adjacent to each other in the waveguide . A region including an intrinsic semiconductor region formed below the absorption region, wherein a recess is formed with respect to the charge region and a region composed of the intrinsic semiconductor region, and the absorption region is And is laminated in the recess (107). In addition, the character and code | symbol in () are illustrations (hereinafter the same).

A second invention of the present invention is a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed, wherein an absorption region (108) and a charge region (105a) for absorbing the signal light are increased. The amplifying region is formed as an avalanche photodiode having a SACM structure separated from the multiplication region (106), and the waveguide includes the charge region and the multiplication region adjacent to each other, and the absorption region Is stacked in a recess formed adjacent to the charge region, and the charge region has a polarity of the first conductivity type and is formed in one adjacent region parallel to the absorption region. A first conductivity type contact region (117) formed on the opposite side of the charge region to the absorption region; and an intrinsic semiconductor region (103) formed below the absorption region. Further wherein the recess is characterized in that it is formed for the charge area, the intrinsic semiconductor region and the first conductivity-type contact region.

According to a fourth aspect of the present invention, both a waveguide-type semiconductor light receiving element formed with a waveguide for receiving signal light and an optical waveguide for guiding the signal light to the waveguide are provided on a support substrate. In the photoelectric fusion module formed integrally, the semiconductor light receiving element is formed as an avalanche photodiode having a SACM structure in which an absorption region that absorbs the signal light, a charge region, and a multiplication region are separated, The waveguide includes a region where the charge region and the multiplication region are adjacent to each other , further includes an intrinsic semiconductor region formed below the absorption region, and includes the charge region and the intrinsic semiconductor region. the region to be a recess is formed, it said absorbing region is stacked on the recess, said optical waveguide core is integrally formed with the multiplication region It is characterized in.

According to a fifth aspect of the present invention, there is provided a method for manufacturing a waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed on an SOI substrate, wherein the semiconductor light receiving element absorbs the signal light. An avalanche photodiode having a SACM structure in which a region, a charge region, and a multiplication region are separated from each other , further comprising an intrinsic semiconductor region formed below the absorption region; and the charge region and the intrinsic region A recess is formed in a region composed of a semiconductor region, and the absorption region is stacked in the recess, and is disposed in the optical waveguide, the charge region, and a region adjacent to the charge region. A Si layer forming process for forming the amplified region on the Si layer of the SOI substrate, a recess forming process for forming a recess adjacent to the charge region, and the recess The absorption region growing process to grow the absorption region of the Ge in the scan, in that it comprises the features.

Claims (14)

A waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed,
An avalanche photodiode having a SACM structure in which an absorption region for absorbing the signal light, a charge region, and a multiplication region are separated from each other;
In the waveguide, the charge region and the multiplication region are formed adjacent to each other,
The semiconductor light receiving element, wherein the absorption region is stacked in a recess formed adjacent to the charge region. The semiconductor light-receiving element according to claim 1,
A contact region of a first conductivity type provided on a surface of the absorption region opposite to the substrate;
A contact region of a second conductivity type adjacent to the multiplication region and provided on the opposite side to the absorption region;
The charge region has a first conductivity type polarity;
The multiplication region and the absorption region are made of an intrinsic semiconductor, and the semiconductor light receiving element. The semiconductor light-receiving element according to claim 2,
The first conductivity type is p-type,
The semiconductor light-receiving element, wherein the second conductivity type is an n-type. The semiconductor light-receiving element according to claim 1,
The charge region has a first conductivity type polarity and is formed in one adjacent region parallel to the absorption region;
A contact region of a first conductivity type formed on the opposite side of the charge region with respect to the absorption region;
An intrinsic semiconductor region formed below the absorption region,
The recess is formed in the charge region, the intrinsic semiconductor region, and the contact region of the first conductivity type. The semiconductor light-receiving element according to claim 1 or 4,
The absorption region is formed of intrinsic Ge,
2. The semiconductor light receiving element according to claim 1, wherein the multiplication region is made of intrinsic Si. A semiconductor light receiving element according to claim 2 or claim 3, wherein
A support substrate;
A first insulating layer interposed between the support substrate and the charge region, the multiplication region, and the second conductivity type contact region;
A first electrode in contact with the contact region of the first conductivity type;
A second electrode in contact with the second conductivity type contact region;
The first insulating layer, the first conductivity type contact region, the charge region, the multiplication region, and the second conductivity type contact region, which are not in contact with the first electrode or the second electrode. And a second insulating layer that covers an undesired region. The semiconductor light receiving element according to claim 6,
The first insulating layer and the second insulating layer are made of SiO ₂ ,
The semiconductor light receiving element, wherein the first electrode and the second electrode are made of Al. A waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed,
An avalanche photodiode having a SACM structure in which an absorption region for absorbing the signal light, a charge region, and a multiplication region are separated from each other;
In the waveguide, the charge region and the multiplication region are formed adjacent to each other,
The multiplication region is disposed in a region adjacent to the charge region,
An intrinsic semiconductor region formed below the absorption region;
Recesses are formed for the charge region and the region composed of the intrinsic semiconductor region,
The semiconductor light receiving element, wherein the absorption region is stacked in the recess. A waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed,
An avalanche photodiode having a SACM structure in which an absorption region that absorbs the signal light, a charge region of a first conductivity type, and a multiplication region are separated;
In the waveguide, the charge region and the multiplication region are formed adjacent to each other,
The multiplication region is an adjacent region of the charge region, and is disposed in a region opposite to the optical axis,
A contact region of a first conductivity type provided in the other adjacent region of the absorption region;
An intrinsic semiconductor region formed below the absorption region;
A recess is formed with respect to a region composed of the charge region, the intrinsic semiconductor region, and the contact region of the first conductivity type,
The semiconductor light receiving element, wherein the absorption region is stacked in the recess. The semiconductor light receiving element according to claim 9,
The multiplication region and the absorption region are made of an intrinsic semiconductor, and the semiconductor light receiving element. A semiconductor light receiving element according to any one of claims 1 to 10,
The optical waveguide for guiding the signal light and the waveguide are integrally formed on a support substrate,
A semiconductor light receiving element, wherein the optical waveguide has a core formed integrally with the multiplication region. A waveguide type semiconductor light receiving element in which a waveguide for receiving signal light is formed,
An avalanche photodiode having a SACM structure in which an absorption region for absorbing the signal light, a charge region, and a multiplication region are separated from each other;
In the waveguide, the charge region and the multiplication region are formed adjacent to each other,
The semiconductor light receiving element, wherein the absorption region is stacked in a region adjacent to the charge region. A photoelectric fusion module in which both a waveguide type semiconductor light receiving element formed with a waveguide for receiving signal light and an optical waveguide for guiding the signal light to the waveguide are integrally formed on a support substrate. There,
An avalanche photodiode having a SACM structure in which an absorption region for absorbing the signal light, a charge region, and a multiplication region are separated from each other;
In the waveguide, the charge region and the multiplication region are formed adjacent to each other,
The absorption region is formed on the surface of a recess formed adjacent to the charge region,
The optical waveguide module has a core formed integrally with the multiplication region. A waveguide-type semiconductor light-receiving element manufacturing method in which a waveguide for receiving signal light via an optical waveguide is formed on an SOI substrate,
The semiconductor light receiving element is formed as an avalanche photodiode having a SACM structure in which an absorption region for absorbing the signal light, a charge region, and a multiplication region are separated from each other.
A Si layer forming process of forming the optical waveguide, the charge region, and a multiplication region disposed in a region adjacent to the charge region on a Si layer of the SOI substrate;
Forming a recess adjacent to the charge region;
An absorption region growth process of growing a Ge absorption region in the recess;
A method for manufacturing a semiconductor light-receiving element.

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