Patent Description:
In recent years, it has been expected that a semiconductor laser using a nitride semiconductor such as GaN, AlGaN, GaInN, for example, is applied as a light source for a high-density optical disk apparatus, a laser beam printer, a full-color display, etc..

An approach to perform scribing and cleaving after crystal-growing a semiconductor layer on a substrate has been proposed as a manufacturing process of this semiconductor laser (PTL <NUM>, for example). <CIT> discloses a wafer having an LD structure formed on a GaN-based substrate, cleavage guide grooves are formed in its surface by scribing from above the LD structure with a diamond needle. The LD structure includes n-GaN contact layer, n-AlGaN clad layer, n-GaN optical guide layer, InGaN multiple quantum well active layer, p-AlGaN evaporation prevention layer, p-GaN optical guide layer, p-AlGaN clad layer, p-GaN contact layer, SiO2 dielectric film, and p-electrodes. <CIT> discloses a group III nitride semiconductor laser device. The semiconductor laser device comprises a laser structure including a support base of the group III nitride and first and second end facets for a laser cavity, and the first and second end facets intersect with an m-n plane defined by the m-axis of the group III nitride and an axis normal to a semipolar primary surface of the support base. <CIT> discloses a method of manufacturing a semiconductor light emitting device employs a substrate formed by successively stacking an n-type semiconductor layered portion including an AlGaN layer, a light emitting layer containing In and a p-type semiconductor layered portion on a group III nitride semiconductor substrate having a larger lattice constant than AlGaN. This method includes the steps of selectively etching the substrate from the side of the p-type semiconductor layered portion along a cutting line to expose the AlGaN layer along the cutting line, forming a division guide groove along the cutting line on the exposed AlGaN layer, and dividing the substrate along the division guide groove. <CIT> discloses a point emission type light emitting element that restricts the light emitting area within a sufficiently tiny region, the point emission type light emitting element is a light emitting element that has stripe ridge comprising an n-type layer, an active layer and a p-type layer that are formed from semiconductors on a substrate.

With an approach of the foregoing PTL <NUM>, however, end surfaces may not be formed perpendicularly, causing variation in a threshold current of each element. Moreover, the end surfaces not being formed perpendicularly reduce a substantial reflectance. Alternatively, guided wave loss occurs to deteriorate characteristics such as the threshold current and slope efficiency.

In a semiconductor light-emitting element that performs formation of the end surfaces, it is desirable to achieve the semiconductor light-emitting element and a method of manufacturing the semiconductor light-emitting element that allow for suppression of characteristic deterioration.

A semiconductor light-emitting element according to an embodiment of the present disclosure includes a stacking structure having a substrate and a semiconductor layer between a first surface and a second surface that face each other in order from a side on which the first surface is located, the substrate including a compound semiconductor, and the semiconductor layer being crystal-grown on the substrate and including a light-emitting region; a first depression formed on at least a portion of a first edge adjacent to the second surface of the stacking structure; and a second depression formed on a second edge extending along a thickness direction of the stacking structure, wherein the second depression is provided as a hole continuously formed from the first surface to the second surface of the stacking structure.

In the semiconductor light-emitting element according to the embodiment of the present disclosure, the stacking structure has the substrate including the compound semiconductor and the semiconductor layer including the light-emitting region in order from the side on which the first surface is located, and the first depression is formed on at least the portion of the first edge adjacent to the second surface. The second depression is formed on the second edge extending along the thickness direction of the stacking structure. Providing the first depression and the second depression makes it easy to secure perpendicularity of an end surface.

A method of manufacturing a semiconductor light-emitting element according to an embodiment of the present disclosure includes: forming a stacking structure having a substrate and a semiconductor layer between a first surface and a second surface that face each other in order from a side on which the first surface is located, the substrate including a compound semiconductor, and the semiconductor layer being crystal-grown on the substrate and including a light-emitting region, the forming of the stacking structure including forming a first depression on at least a portion of a first edge adjacent to the second surface of the stacking structure, and forming a second depression on a second edge extending along a thickness direction of the stacking structure.

In the method of manufacturing the semiconductor light-emitting element according to the embodiment of the present disclosure, in the forming of the stacking structure having the substrate including the compound semiconductor and the semiconductor layer including the light-emitting region in order from the side on which the first surface is located, the first depression is formed on at least the portion of the first edge adjacent to the second surface and the second depression is formed on the second edge extending along the thickness direction of the stacking structure. Forming the first and second depressions makes it easy to secure perpendicularity of an end surface.

In the semiconductor light-emitting element according to the embodiment of the disclosure, the stacking structure has the substrate including the compound semiconductor and the semiconductor layer including the light-emitting region in order from the side on which the first surface is located, and the first depression is formed on at least the portion of the first edge adjacent to the second surface. The second depression is formed on the second edge extending along the thickness direction of the stacking structure. Providing the first and second depressions makes it possible to secure perpendicularity of the end surface and suppress deterioration in a threshold current, slope efficiency, etc. Therefore, it is possible to suppress characteristic deterioration.

In the method of manufacturing the semiconductor light-emitting element according to the embodiment of the present disclosure, in the forming of the stacking structure having the substrate including the compound semiconductor and the semiconductor layer including the light-emitting region in order from the side on which the first surface is located, the first depression is formed on at least the portion of the first edge adjacent to the second surface and the second depression is formed on the second edge extending along the thickness direction of the stacking structure. Forming the first and second depressions makes it possible to secure perpendicularity of the end surface and suppress deterioration in a threshold current, the slope efficiency, etc. Therefore, it is possible to suppress characteristic deterioration.

It is to be noted that effects of the present disclosure are not necessarily limited to those described above, and may be any of effects that are described herein.

In the following, some embodiments of the present disclosure are described in detail with reference to the drawings. The embodiments described below each illustrate a specific example of the present disclosure, and the present disclosure is not limited to the following embodiments. Moreover, the present disclosure is not limited to positions, dimensions, dimension ratios, and other factors of respective components illustrated in the drawings. It is to be noted that description is given in the following order.

<FIG> illustrates a configuration example of a semiconductor light-emitting element <NUM> according to an embodiment of the present disclosure. The semiconductor light-emitting element <NUM> is preferably used as a light source for a high-density optical disk apparatus, a laser beam printer, a full-color display, etc., for example. The semiconductor light-emitting element <NUM> includes a stacking structure <NUM> having a first surface S1 and a second surface S2 facing each other. The stacking structure <NUM> includes, for example, a substrate <NUM> and a semiconductor layer <NUM> formed on the substrate <NUM> by crystal growth. A band-like projection <NUM> and an upper electrode <NUM> (for example, a p-side electrode) are provided on the second surface S2 of the stacking structure <NUM>. An unillustrated lower electrode (for example, an n-side electrode) is electrically coupled to the substrate <NUM> of the stacking structure <NUM>. The lower electrode is formed on a back surface of the first surface S1, for example.

The semiconductor light-emitting element <NUM> is, for example, an edge-emitting semiconductor laser, and has a pair of end surfaces S3 and S4 (a first end surface and a second end surface), with an extending direction of the projection <NUM> as a resonator direction (a Y direction). Note that the semiconductor light-emitting element <NUM> is not limited to such a semiconductor laser, and may be a semiconductor light-emitting element such as an edge-emitting light-emitting diode (LED: Light Emitting Diode) or a superluminescent diode (SLD: Superluminescent diode), for example.

The substrate <NUM> includes a compound semiconductor, for example, a group III-V nitride semiconductor such as GaN. Here, the "group III-V nitride semiconductor" refers to a semiconductor including at least one kind of a group of 3B group elements in the short-form periodic table and at least N of 5B group elements in the short-form periodic table. Examples of the group III-V nitride semiconductor include a gallium nitride-based compound including Ga and N. Examples of the gallium nitride-based compound include GaN, AlGaN, AlGaInN, etc. The group III-IV nitride semiconductor may be doped with an n-type impurity of a group IV or group VI element such as Si, Ge, O, or Se, or an p-type impurity of a group II or group IV element such as Mg, Zn, or C, as needed.

The substrate <NUM> has a semipolar surface, for example. That is, the substrate <NUM> has a main surface inclined at a predetermined angle (about <NUM> degrees or more and about <NUM> degrees or less, for example) in an m-axis direction from a c-plane, for example.

The semiconductor layer <NUM> includes a group III-V nitride semiconductor, for example, and is formed by an epitaxial crystal growth method such as an MOCVD (Metal Organic Chemical Vapor Deposition) method, for example, with the main surface of the substrate <NUM> as a crystal growth plane. The semiconductor layer <NUM> includes an active layer <NUM> that forms a light-emitting region 21A. Specifically, the semiconductor layer <NUM> has, for example, a lower cladding layer (an n-type cladding layer, for example), the active layer <NUM>, an upper cladding layer (a p-type cladding layer, for example), and a contact layer (a p-type contact layer, for example), etc. in order from a side on which the substrate <NUM> is located. The lower cladding layer includes AlGaN, for example. The active layer <NUM> has, for example, a multiple quantum well structure including well layers and barrier layers that are alternately stacked. The well layers and the barrier layers include GaInN having mutually different composition ratios. The upper cladding layer includes AlGaN, for example. The contact layer includes GaN, for example. It is to be noted that any layer (a buffer layer, a guide layer, etc., for example) other than the foregoing layers may be further provided in the semiconductor layer <NUM>. The upper electrode <NUM> is formed on the semiconductor layer <NUM>.

The upper electrode <NUM> includes a laminated film including titanium (Ti), platinum (Pt), and gold (Au), for example. In contrast, the lower electrode formed on the back surface (the first surface S1) of the substrate <NUM> includes, for example, a laminated film including an alloy of gold (Au) and germanium (Ge), nickel (Ni), and gold (Au).

The projection <NUM> is a ridge including the foregoing contact layer and the foregoing upper cladding layer, for example. The projection <NUM> is insulated by an insulating film such as SiO<NUM>, after the contact layer and a portion of the upper cladding layer are removed by etching.

The end surfaces S3 and S4 of the stacking structure <NUM> are cleaved surfaces formed by cleaving. A resonator structure is formed through sandwiching the semiconductor layer <NUM> between the end surfaces S3 and S4. The end surface S3 is a surface that includes the light-emitting region 21A and emits laser light. A multilayer reflection film (not illustrated) is formed on a surface of the end surface S3. The multilayer reflection film formed on the surface of the end surface S3 is a low reflection film. A reflectance adjusted by a combination of the multilayer reflection film and the end surface S3 is about <NUM>%, for example. The end surface S4 is a surface that reflects laser light, and a multilayer reflection film (not illustrated) is also formed on a surface of the end surface S4. The multilayer reflection film formed on the surface of the end surface S4 is a high reflection film. A reflectance adjusted by a combination of the multilayer reflection film and the end surface S4 is about <NUM>%, for example.

It is possible to form the end surfaces S3 and S4 by cleaving that utilizes a groove or a notch (a first depression <NUM>, a second depression <NUM>, and a third depression <NUM>) formed by scribing.

In the present embodiment, the first depression <NUM> is formed on at least a portion of an edge e1 adjacent to the second surface S2 of the stacking structure <NUM>. The second depression <NUM> is formed on an edge e2 extending along a thickness direction (a Z direction) of the stacking structure <NUM>. The third depression <NUM> is formed on at least a portion of an edge e3 adjacent to the first surface S1 of the stacking structure <NUM>.

Here, the stacking structure <NUM> has a rectangular parallelepiped shape, for example, and includes, for example, six surfaces including the first surface S1, the second surface S2, and the end surfaces S3 and S4, eight sides, and eight apexes. The edge e1 is a portion corresponding to a side adjacent to the second surface S2 and the end surface S3 and a side adjacent to the second surface S2 and the end surface S4. The edge e1 extends along an element width direction (an X direction). The edge e2 is a portion that extends along the thickness direction (the Z direction) and corresponds to one or both of two sides adjacent to the respective end surfaces S3 and S4. The edge e3 is a portion corresponding to a side adjacent to the first surface S1 and the end surface S3 and a side adjacent to the first surface S1 and the end surface S4. The edge e3 faces the edge e1, for example, and extends along the element width direction (the X direction).

The first depression <NUM> is formed on a portion of the edge e1, excluding a region corresponding to the light-emitting region 21A, for example. Specifically, the first depression <NUM> is provided on one or both of two regions sandwiching the light-emitting region 21A of the semiconductor layer <NUM> in between. In this example, the first depression <NUM> is provided on each of the two regions sandwiching the light-emitting region 21A in between. A depth t (a length along the Z direction) of the first depression <NUM> is <NUM> or larger and <NUM> or smaller, for example. A narrower width b (a length along the Y direction) of the first depression <NUM> is more favorable, and the width b of the first depression <NUM> is desirably <NUM> or smaller, for example. Providing the first depression <NUM> (a fourth depression 32A to be described later) makes it possible to concentrate stress on the first depression <NUM> (the fourth depression 32A) and form the end surfaces S3 and S4 with high perpendicularity during cleaving.

The second depression <NUM> is continuously formed from the first surface S1 to the second surface S2 on the edge e2, for example. In this example, the second depression <NUM> is provided on each of four edges e2 corresponding to the four sides extending in the Z direction. Providing the second depression <NUM> (a hole 33A to be described later) makes it possible to make a rate of crack propagation between elements constant and suppress variation in perpendicularity or flatness of the end surfaces during cleaving.

The third depression <NUM> continuously extends along the X direction and is provided on the edge e3, for example. A depth (a length along the Z direction) of the third depression <NUM> is <NUM> or larger and <NUM> or smaller, for example, and may be the same as or different from the depth of the first depression <NUM>. Providing the third depression <NUM> makes it possible to improve perpendicularity of the end surfaces during cleaving.

A cross-sectional shape (an XZ cross-sectional shape) of each of the first depression <NUM>, the second depression <NUM>, and the third depression <NUM> has a quadrangular shape (a rectangular shape or square shape), for example. Corners of the quadrangular shape may be rounded. The first depression <NUM> and the second depression <NUM> of the first depression <NUM>, the second depression <NUM>, and the third depression <NUM> are provided so as to be adjacent to (connected with) each other, for example, and the third depression <NUM> and the second depression <NUM> are provided so as to be adjacent to each other, for example. Here, in a case where the first depression <NUM> and the second depression <NUM> are spaced apart, stress easily concentrates on the second depression <NUM>. Thus, the first depression <NUM> and the second depression <NUM> are desirably provided adjacently. The width (the length along the extending direction of the edge e1 (the X direction)) of the first depression <NUM> is desirably larger than the width (the length along the extending direction of the edge e1 (the X direction)) of the second depression <NUM>, which makes it possible to concentrate stress on the first depression <NUM> (the fourth depression 32A to be described later) rather than on the second depression <NUM> (the hole 33A to be described later) and form the end surfaces S3 and S4 with higher perpendicularity in cleaving.

<FIG> illustrates a schematic configuration of the semiconductor light-emitting element <NUM> (the stacking structure <NUM>). <FIG> schematically illustrates a planar configuration (an XY planar configuration viewed from a side on which the second surface S2 is located) before cleaving of the semiconductor light-emitting element <NUM>. <FIG> illustrates a cross-sectional configuration (an XZ cross-sectional configuration) of <FIG>. As can be seen from the above, the semiconductor light-emitting element <NUM> configures one (a portion of an element substrate 1B) of a plurality of element regions 1A that are two-dimensionally disposed in a state before the cleaving.

The fourth depression 32A corresponding to the foregoing first depression <NUM> and the hole 33A corresponding to the second depression <NUM> are formed on the element substrate 1B. As can be seen from the above, in the element substrate 1B before being cleaved, the fourth depression 32A and the hole 33A are provided in a region between the respective semiconductor light-emitting elements <NUM> (element regions 1A). Specifically, the fourth depression 32A and the hole 33A are formed in each of regions corresponding to four corners of the respective element regions 1A. In the element substrate 1B, for example, a plurality of fourth depressions 32A are formed discretely in portions excluding the projection <NUM> (that is, the light-emitting region 21A) and represent broken lines extending in the X direction, for example. The hole 33A is provided in a middle portion of each of the fourth depressions 32A, for example, and penetrates from the first surface S1 to the second surface S2. In contrast, a fifth depression 34A corresponding to the third depression <NUM> is formed on a side on which the first surface S1 is located. The fifth depression 34A is continuously formed so as to extend along the X direction.

A depth d1 (a length along the X direction) of the fourth depression 32A is desirably larger than a width (diameter) d2 (a length along the X direction) of the hole 33A. As described above, a reason for this is that it is possible to concentrate stress on the fourth depression 32A and form the end surfaces S3 and S4 with higher perpendicularity in cleaving. It is possible to form any of the fourth depression 32A, the hole 33A, and the fifth depression 34A by laser irradiation (laser scribing), for example. It is to be noted that although the laser scribing is desirable as a method of forming the fourth depression 32A, the hole 33A, and the fifth depression 34A, for example, any other method such as cutting and etching may be used.

A method of manufacturing the semiconductor light-emitting element <NUM> is described below. <FIG> illustrates a flow of a manufacturing process of the semiconductor light-emitting element <NUM>.

First, the substrate <NUM> including GaN, for example, is prepared as a wafer (step S11). The semiconductor layer <NUM> including the nitride semiconductor is formed collectively on the substrate <NUM> by the epitaxial crystal growth method such as the MOCVD method, for example (step S12). At this time, it is possible to use, for example, trimethyl aluminum (TMAl), trimethylgallium (TMGa), trimethyl indium (TMIn), ammonia (NH<NUM>), etc. as a raw material of the compound semiconductor, for example, monosilane (SiH<NUM>) as a raw material of a donor impurity, and, for example, bis(cyclopentadienyl)magnesium (Cp<NUM>Mg) as a raw material of an acceptor impurity. Thereafter, the projection <NUM> is formed. Specifically, the projection <NUM> is formed through removing a portion of the upper cladding layer of the semiconductor layer <NUM> by dry etching. After the insulating film including SiO<NUM> or the like is formed on the projection <NUM>, the insulating film on an upper surface of the projection <NUM> is removed by a photolithography method and etching.

Subsequently, the substrate <NUM> is polished (thinned) and the electrodes (upper electrode <NUM> and the lower electrode) are formed (step S13). Thus, the substrate <NUM> is thinned from, for example, the thickness of about <NUM> or larger and <NUM> or smaller to about <NUM> or smaller, for example. It is to be noted that the electrodes may be formed after the substrate <NUM> is polished, or the substrate <NUM> may be polished after the upper electrode <NUM> is formed and thereafter the lower electrode may be formed on a back surface of the substrate <NUM>. The upper substrate <NUM> is formed on the second surface S2 so as to cover the projection <NUM>.

Next, the first depression <NUM> (the fourth depression 32A), the second depression <NUM> (hole 33A), and the third depression <NUM> (the fifth depression 34A) are formed by laser scribing (laser irradiation), for example (step S14). Specifically, as illustrated in <FIG>, laser light irradiation is performed while scanning the laser along the X direction on the second surface S2 of the element substrate 1B to form the fourth depression 32A. In addition, as illustrated in <FIG>, laser light irradiation is performed while scanning the laser along the X direction on the first surface S1 of the element substrate 1B to form the fifth depression 34A. Although either the fourth depression 32A or the fifth depression 34A may be formed first, the fourth depression 32A and the fifth depression 34A are desirably formed at positions facing each other. At this time, in a case where the stacking structure <NUM> has transparency, it is possible to see through the stacking structure <NUM> and visually recognize, the fourth depression 32A (or the fifth depression 34A) that is formed first, from a side on which the first surface S1 (or the second surface S4) is located, which allows for alignment of the fourth depression 32A and the fifth depression 34A. Alternatively, it is possible to form the fourth depression 32A and the fifth depression 34A at the positions facing each other with reference to a formation pattern of the upper electrode <NUM> and the lower electrode formed on the element substrate 1B.

In contrast, the second depression <NUM> (the hole 33A) is formed, for example, after the fourth depression 32A and the fifth depression 34A are formed. However, order of forming these depressions is not particularly limited. The hole 33A may be formed before the fourth depression 32A and the fifth depression 34A are formed, or the hole 33A may be formed after the fourth depression 32A (or the fifth depression 34A) is formed and lastly the fifth depression 34A (or the fourth depression 32A) may be formed. Specifically, as illustrated in <FIG>, it is possible to form the hole 33A penetrating through the stacking structure <NUM>, by the laser light irradiation from a side on which the first surface S1 or the second surface S2 of the element substrate 1B is located.

A region corresponding to the fourth depression 32A and the hole 33A (a region along the extending direction of the edge e1) is a cleaving line of the element substrate 1B.

In this laser scribing, a laser that outputs a wavelength absorbable by a constituent material of the substrate <NUM>, for example, is used. For example, in a case where a GaN substrate is used, a laser that outputs a wavelength near <NUM> is used. In addition, adjustment of laser irradiation conditions (such as power, irradiation time, and a spot diameter) makes it possible to control a width (a diameter), a depth, etc. of each of the fourth depression 32A, the fifth depression 34A, and the hole 33A.

Next, cleaving is performed to form the end surfaces S3 and S4 of the stacking structure <NUM> and separate the semiconductor light-emitting elements <NUM> (element regions 1A) (Step S15). At this time, the element substrate 1B is pressed along the extending direction (the X direction) of each of the fourth depression 32A and the fifth depression 34A formed on the element substrate 1B as a cleaving line L. <FIG> schematically illustrate an example of a cleaving method.

As illustrated in <FIG>, the element substrate 1B is fixed to a surface of an adhesive sheet <NUM>, and covered by a PET film <NUM> to protect the element substrate 1B. The element substrate 1B sandwiched between the adhesive sheet <NUM> and the PET film <NUM> is placed on a pair of receiving blades <NUM>, and thereafter the element substrate 1B is pressed using a blade <NUM>. Accordingly, the element substrate 1B is cleaved along the cleaving line L. This cleaving is repeatedly performed on respective lines along the X direction between the element regions 1A illustrated in <FIG>.

Thus, the end surfaces S3 and S4 are formed and the plurality of semiconductor light-emitting elements <NUM> are obtained. The semiconductor light-emitting elements are arranged in a bar shape (arranged continuously along the X direction). After the multilayer reflection film is formed on the end surfaces S3 and S4 of the semiconductor light-emitting elements <NUM> arranged in the bar shape, regions between the elements along the Y direction are also scribed, and cleaved similarly as described above. The element substrate 1B is divided into the plurality of element regions 1A (the semiconductor light-emitting elements <NUM>) in such a manner. Thus, the semiconductor light-emitting element <NUM> illustrated in <FIG> is completed.

In the semiconductor light-emitting element <NUM> according to the present embodiment, in a case where a predetermined voltage is applied between the upper electrode <NUM> and the lower electrode, an electric current is injected into the active layer <NUM> of the semiconductor layer <NUM>, which results in light emission by recombination of electrons and holes. Light generated in the active layer <NUM> is repeatedly reflected on the end surfaces S3 and S4 which configure a pair of resonator mirrors, for example, and thereafter, the light is outputted with a predetermined oscillation wavelength λ from the light-emitting region 21A on the end surface S3 (laser oscillation occurs).

In the semiconductor light-emitting element <NUM>, the end surfaces S3 and S4 as the resonator mirrors are formed by cleaving.

However, the end surfaces formed by cleaving may not be formed perpendicularly. Poor perpendicularity of the end surfaces may cause variation in a threshold current in each of the elements or reduce substantial reflectance. Alternatively, guided wave loss occurs to deteriorate characteristics such as the threshold current or slope efficiency. In particular, in a case where the semiconductor layer is crystal-grown on a semipolar plane, and cleaving is performed as with a case where the semiconductor layer is crystal-grown on a [<NUM>] plane, for example, perpendicularity is susceptible to an influence of the [<NUM>] plane that is a substrate crystal plane near each of the end surfaces. Thus, the end surfaces are not formed perpendicularly, thereby causing variation in the threshold current. As can be seen from the above, poor perpendicularity of the end surfaces reduces substantial reflectance, or results in guided wave loss, thereby easily deteriorating the characteristics such as the threshold current or the slope efficiency.

It is to be noted that the foregoing PTL1, for example, proposes the method of forming a scribed hole in a wafer where a semiconductor layer is crystal-grown on a semipolar plane of a substrate, and then cleaving the wafer. The scribed hole penetrates through the wafer. However, in the scribed hole, a scribed width (a length along a resonator length direction) viewed from a P plane increases. Variation in a length along a resonator direction occurs on a cross-section of the element divided with use of such a scribed hole. In other words, perpendicularity of the end surfaces formed by cleaving degrades.

In contrast to this, in the present embodiment, the first depression <NUM> is formed on at least a portion of the edge e1 adjacent to the second surface S2 of the stacking structure <NUM>, and the second depression <NUM> is formed on the edge e2 extending along the thickness direction of the stacking structure <NUM>. Providing the first depression <NUM> and the second depression <NUM> makes it easy to secure perpendicularity of the end surfaces S3 and S4. Specifically, it is possible to make the rate of crack propagation between elements constant by the second depression <NUM> (the hole 33A) while concentrating stress in cleaving on the first depression <NUM> (the fourth depression 32A), which makes it easy to form the end surfaces S3 and S4 perpendicularly. Moreover, it is possible to suppress unevenness of the end surfaces S3 and S4 and enhance flatness. This makes it possible to suppress deterioration in the threshold current, the slope efficiency, etc. of the semiconductor light-emitting element <NUM>.

Further, in the present embodiment, providing the first depression <NUM> and the second depression <NUM> makes it easy to secure linearity of the cleaving line, which makes it easier to secure perpendicularity of the end surfaces S3 and S4.

Furthermore, in the present embodiment, providing the first depression <NUM> and the second depression <NUM> makes it possible to suppress occurrence of a fine break, as compared with a case where only the first depression <NUM> or only the second depression <NUM> is provided.

In addition, in the present embodiment, flatness of the end surfaces S3 and S4 is enhanced, which makes it possible to improve ESD (Electrostatic Discharge: electrostatic discharge) resistance or COD (Catastrophic Optical Damage: optical damage) resistance.

As described above, in the present embodiment, the first depression <NUM> is formed on at least a portion of the edge e1 adjacent to the second surface S2 of the stacking structure <NUM>, and the second depression <NUM> is formed on the edge e2 extending along the thickness direction of the stacking structure <NUM>. This makes it possible to secure perpendicularity of the end surfaces S3 and S4 and suppress deterioration in the threshold current, the slope efficiency, etc. of the semiconductor light-emitting element <NUM>. It is also possible to suppress characteristic variation in each of the semiconductor light-emitting elements <NUM>. Therefore, it is possible to suppress characteristic deterioration.

Next, description is given of modification examples of the foregoing embodiment. It is to be noted that components similar to those in the foregoing embodiment are denoted by same reference numerals, and description thereof is omitted where appropriate.

<FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. <FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. <FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element (the element region 1A) according to Modification Example <NUM>-<NUM>. It is to be noted that <FIG> illustrate a state of the element substrate 1B (a state before cleaving).

Although the foregoing embodiment exemplifies the configuration in which the first depression <NUM> is adjacent to the second depression <NUM>, the first depression <NUM> and the second depression <NUM> may not be adjacent. As in Modification Examples <NUM>-<NUM> to <NUM>-<NUM>, the first depression <NUM> and the second depression <NUM> may be spaced apart (so as not to overlap each other). Moreover, as in Modification Examples <NUM>-<NUM> and <NUM>-<NUM>, the first depression <NUM> may be provided only on a portion corresponding to one side (one of two regions sandwiching the light-emitting region 21A in between) of the light-emitting region 21A (not illustrated in <FIG>).

As can be seen from the above, a forming position of the first depression <NUM> and the number of first depressions <NUM> are not particularly limited, and it is only necessary to provide the first depression <NUM> on at least a portion of the edge e1 adjacent to the second surface S2 of the stacking structure <NUM>.

<FIG> is a plan view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>. <FIG> is a diagram illustrating a cross-sectional configuration of the semiconductor light-emitting element illustrated in <FIG>. It is to be noted that <FIG> illustrate the state of the element substrate 1B (the state before cleaving).

Although the foregoing embodiment exemplifies the configuration in which the second depressions <NUM> are formed on the four edges e2 of the semiconductor light-emitting element <NUM> (at the four corners of the element region 1A), the second depressions <NUM> may be provided only on some of the four edges e2. In other words, in the element substrate 1B, a smaller number of second depressions <NUM> (the holes 33A) than that in the foregoing embodiment may be provided.

<FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. <FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. It is to be noted that <FIG> illustrate the state of the element substrate 1B (the state before cleaving).

Although the foregoing embodiment exemplifies the case where the cross-sectional shape of the second depression <NUM> is the rectangular shape or the square shape, the cross-sectional shape of the second depression <NUM> is not limited thereto, and may be a trapezoidal shape or a triangular shape as in Modification Examples <NUM>-<NUM> and <NUM>-<NUM>. In this case, in the element substrate 1B, as illustrated in <FIG>, the second depression <NUM> (the hole 33A) is formed so as to have a diameter (a width) that gradually increases from the first surface S1 to the second surface S2. Laser light irradiation is performed in laser scribing while gradually increasing (or reducing) laser output to form one hole 33A, which makes it possible to form such a shape.

<FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. <FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. It is to be noted that <FIG> and <FIG> illustrate the state of the element substrate 1B (the state before cleaving).

Although the foregoing embodiment exemplifies the case where the cross-sectional shapes of the first depression <NUM> and the third depression <NUM> are the rectangular shape or the square shape, the cross-sectional shapes of the first depression <NUM> and the third depression <NUM> are not limited thereto, and may be a trapezoidal shape or a triangular shape, as in Modification Examples <NUM>-<NUM> and <NUM>-<NUM>. In other words, the first depression <NUM> and the third depression <NUM> may have a tapered shape (an inclined surface). Moreover, although not illustrated specifically, the respective cross-sectional shapes of the first depression <NUM> and the third depression <NUM> may be the same or different.

<FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. <FIG> is a cross-sectional view of a configuration example of a semiconductor light-emitting element according to Modification Example <NUM>-<NUM>. It is to be noted that <FIG> illustrate the state of the element substrate 1B (state before cleaving).

Although the foregoing embodiment exemplifies the configuration in which the third depression <NUM> is provided continuously along the extending direction of the edge e3 on the side on which the first surface S1 is located, the third depression <NUM> may be provided only in a selective region of the edge e3, as in Modification Example <NUM>-<NUM>. In this case, as illustrated in <FIG>, in the element substrate 1B, a plurality of third depressions <NUM> are discretely formed along the extending direction of the edge e3. Moreover, although the third depression <NUM> is spaced apart from the second depression <NUM> in the example in <FIG>, the third depression <NUM> may be provided adjacent to the second depression <NUM>.

Further, as in Modification Example <NUM>-<NUM>, the third depression <NUM> may not be provided. As long as the first depression <NUM> and the second depression <NUM> are provided, it is possible to secure perpendicularity of the end surfaces S3 and S4.

Although the description has been given by referring to the embodiment and the modification examples, the present disclosure is not limited to the foregoing embodiment, etc., and may be modified in a variety of ways. It is to be noted that the effects described herein are merely illustrative. The effects of the present disclosure are not limited to those described herein. The present disclosure may further have any effects other than those described herein. In any case, the invention is defined by the appended independent claims. Optional features are further defined by the dependent claims.

Claim 1:
A semiconductor light-emitting element (<NUM>), comprising:
a stacking structure (<NUM>) having a substrate (<NUM>) and a semiconductor layer (<NUM>) between a first surface (S1) and a second surface (S2) that face each other in order from a side on which the first surface (S1) is located, the substrate (<NUM>) including a compound semiconductor, and the semiconductor layer (<NUM>) being crystal-grown on the substrate (<NUM>) and including a light-emitting region (21A);
a first depression (<NUM>) formed on at least a portion of a first edge (e1) adjacent to the second surface (S2) of the stacking structure (<NUM>), and wherein the first depression (<NUM>) is formed on a portion of the first edge (e1), excluding a region corresponding to the light-emitting region (21A); and
a second depression (<NUM>) formed on a second edge (e2) extending along a thickness direction of the stacking structure (<NUM>),
characterised in that
the second depression is provided as a quarter-circular recess continuously formed from the first surface (S1) to the second surface (S2), part of a hole (33A) penetrating the stacking structure upon fabrication.