KR102407827B1 - Light emitting device - Google Patents

Abstract

A light emitting device is disclosed. The light emitting device includes: a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer; first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively; an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes; a stress buffer layer positioned on the insulating layer; light emitting structure and stress buffer layer located on the light emitting structure and the insulating layer, the first and second bulk electrodes being electrically connected to the first and second contact electrodes, respectively; and an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing top surfaces of the first and second bulk electrodes, wherein the first bulk electrode includes the first and second bulk electrodes. The electrode includes a protrusion protruding from side surfaces opposite to each other, and the second bulk electrode includes a concave portion recessed from the side surface where the first and second bulk electrodes face each other.

Description

Light emitting device {LIGHT EMITTING DEVICE}

The present invention relates to a light emitting device, and more particularly, to a light emitting device having improved mechanical stability and heat dissipation efficiency.

Recently, as the demand for a small high-power light emitting device increases, the demand for a large-area flip-chip type light emitting device having excellent heat dissipation efficiency is increasing. The electrode of the flip chip light emitting device is directly bonded to the secondary substrate, and since a wire for supplying external power to the flip chip light emitting device is not used, heat dissipation efficiency is very high compared to that of the horizontal light emitting device. Therefore, even when a high-density current is applied, heat can be effectively conducted to the secondary substrate side, and thus the flip-chip type light emitting device is suitable as a high output light emitting source.

In addition, for miniaturization and high output of the light emitting device, a process of packaging the light emitting device in a separate housing is omitted and the demand for a chip scale package using the light emitting device itself as a package is increasing. In particular, since the electrode of the flip-chip type light emitting device can function similarly to the lead of the package, the flip chip type light emitting device can be usefully applied even in such a chip scale package.

When such a chip-scale package type device is used as a high-power light emitting device, a high-density current is applied to the chip-scale package. When a high-density current is applied, the heat generated from the light emitting chip increases accordingly. Such heat generates thermal stress in the light emitting device, and generates a stress generated at an interface between materials having different coefficients of thermal expansion and residual stress resulting therefrom.

In particular, when a crack occurs between the electrodes due to such stress, the probability that the light emitting device is destroyed is high, thereby causing defects in the light emitting device. Therefore, a light emitting device applied to a high power light emitting device is required to have high heat dissipation efficiency and excellent mechanical stability.

The problem to be solved by the present invention is to provide a light emitting device having excellent mechanical stability, and a reduced probability of failure, and a method for manufacturing the same.

A light emitting device according to an aspect of the present invention is a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer ; first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively; an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes; a stress buffer layer positioned on the insulating layer; first and second bulk electrodes disposed on the light emitting structure and the stress buffer layer and electrically connected to the first and second contact electrodes, respectively; and an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes, wherein the first bulk electrode comprises: and a protrusion protruding from a side surface of the second bulk electrode facing each other, wherein the second bulk electrode includes a concave portion recessed from a side surface of the first and second bulk electrodes facing each other.

The protrusion may engage the concave portion.

A width of the protrusion may change along a protruding direction.

A width of the protrusion may decrease along a protruding direction, and a width of the concave portion may decrease along a recessed direction.

Each of the protrusions and the concave portions may be formed in plurality, and the plurality of protrusions may be engaged with the plurality of concave portions.

The insulating layer may include a first insulating layer and a second insulating layer, wherein the first insulating layer partially covers the second contact electrode and partially covers the first conductivity-type semiconductor layer and the second contact electrode, respectively. may include a first opening and a second opening exposed to A third opening and a fourth opening partially exposing the first contact electrode and the second contact electrode may be included.

The light emitting device may further include a connection electrode positioned between the second contact electrode and the second bulk electrode, and the connection electrode may be formed of the same material as the first contact electrode.

A portion of the first insulating layer may be interposed between the first contact electrode and the second contact electrode.

The light emitting device may further include a connection electrode positioned on the second contact electrode, and the insulating layer may include a first opening and a second opening exposing the first contact electrode and the connection electrode, respectively. can

The light emitting structure may include a region in which the first conductivity-type semiconductor layer is partially exposed, and the first contact electrode may be located in a region in which the first conductivity-type semiconductor layer is partially exposed.

The light emitting structure may include a plurality of holes partially exposing the first conductivity type semiconductor layer, and the first contact electrode may be electrically connected to the first conductivity type semiconductor layer through the plurality of holes. .

The light emitting device may further include a first pad electrode and a second pad electrode positioned on each of the first and second bulk electrodes, and the insulating support is formed of the first and second bulk electrodes. A portion of the upper surface may be covered, and the insulating support may surround side surfaces of the first and second pad electrodes.

The first pad electrode may not be positioned on the protrusion.

A surface area of the first pad electrode and the second pad electrode may be the same.

The light emitting device may further include a wavelength conversion unit positioned on a lower surface of the light emitting structure.

A separation distance between the first bulk electrode and the second bulk electrode may be constant.

A horizontal cross-sectional area of the first bulk electrode may be greater than a horizontal cross-sectional area of the second bulk electrode.

The protrusion of the first bulk electrode may include a first protrusion and a second protrusion protruding from the first protrusion, and the concave portion of the second bulk electrode further includes a first concave portion and a further protrusion from the first concave portion. and a recessed second recess.

The second protrusion may be positioned at a position that vertically overlaps with the central portion of the light emitting device.

The second protrusion may be formed as at least a part of a polygonal, circular, or elliptical shape having an inscribed circle having a diameter of 50 μm or more with a central point of the light emitting device as an origin.

A light emitting device according to another aspect of the present invention, a light emitting structure comprising a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer ; a first contact electrode and a second contact electrode disposed on the light emitting structure and having an ohmic contact with the first and second conductivity-type semiconductor layers, respectively; an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes; first and second bulk electrodes disposed on the light emitting structure and the insulating layer and electrically connected to the first and second contact electrodes, respectively; and an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes, wherein the first and second bulk electrodes are provided. An imaginary line extending along a spaced region of portions opposite to each other has at least one bent portion, and a horizontal cross-sectional area of the first bulk electrode is greater than a horizontal cross-sectional area of the second bulk electrode.

The starting point and the ending point of the virtual line may be located on the same line.

A light emitting device according to another aspect of the present invention includes a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer. structure; first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively; an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes; first and second bulk electrodes disposed on the insulating layer and electrically connected to the first and second contact electrodes, respectively; and an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes, wherein the first bulk electrode comprises: and a first protrusion protruding from a side surface of which the second bulk electrode faces each other, and a second protrusion protruding from the first protrusion part, wherein the second bulk electrode includes the first and second bulk electrodes facing each other. a first concave portion recessed from the side, and a second concave portion further recessed from the first concave portion, wherein the second protrusion has at least a polygonal, circular or elliptical shape having an inscribed circle having a central point of the light emitting element as its origin. formed in part

According to the present invention, there is provided a light emitting device including first and second bulk electrodes each having a protrusion and a concave portion. Accordingly, it is possible to suppress the occurrence of a peeling phenomenon between the bulk electrodes and the insulating support, and improve the mechanical stability of the insulating support, thereby improving the reliability of the light emitting device. In addition, there is provided a light emitting device having improved heat dissipation efficiency by forming different horizontal cross-sectional areas of the bulk electrode.

In addition, since the protrusion of the first bulk electrode is disposed at a position overlapping the central portion of the light emitting device in a vertical direction, the mechanical stability of the light emitting device can be improved, and defects or damage to the insulating support during the manufacturing process of the light emitting device can be prevented. By effectively preventing it, it is possible to improve the manufacturing yield of the light emitting device.

1 and 2 are a plan view and a cross-sectional view for explaining a light emitting device according to an embodiment of the present invention.
3 is a plan view for explaining a light emitting device according to embodiments of the present invention.
4 and 5 are a plan view and a cross-sectional view for explaining a light emitting device according to another embodiment of the present invention.
6 and 7 are a plan view and a cross-sectional view for explaining a light emitting device according to another embodiment of the present invention.
8 and 9 are plan views and cross-sectional views illustrating a light emitting device according to another embodiment of the present invention.
10 to 25 are plan views and cross-sectional views for explaining a light emitting device and a method of manufacturing the same according to other embodiments of the present invention.
26 is an exploded perspective view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a lighting device.
27 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a display device.
28 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a display device.
29 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a head lamp.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The embodiments introduced below are provided as examples so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art to which the present invention pertains. Accordingly, the present invention is not limited to the embodiments described below and may be embodied in other forms. And, in the drawings, the width, length, thickness, etc. of the components may be exaggerated for convenience. In addition, when one component is described as being “on” or “on” another component, each component is different from each component as well as when each component is “immediately above” or “directly on” the other component. It includes the case where another component is interposed between them. Like reference numerals refer to like elements throughout.

1 and 2 are a plan view and a cross-sectional view for explaining a light emitting device according to an embodiment of the present invention. FIG. 2 is a cross-sectional view of a portion corresponding to line I-I' of FIG. 1 . 3 is a plan view for explaining a light emitting device according to embodiments of the present invention.

1 and 2, the light emitting device includes a light emitting structure 220, a first contact electrode 230, a second contact electrode 240, insulating layers 250 and 260, first and second bulk electrodes ( 271 , 273 ) and an insulating support 280 . Furthermore, the light emitting device may further include a growth substrate (not shown), a connection electrode 245 , and a stress buffer layer 265 .

The light emitting structure 220 includes a first conductivity type semiconductor layer 221 , an active layer 223 disposed on the first conductivity type semiconductor layer 221 , and a second conductivity type semiconductor layer ( 225). The first conductivity type semiconductor layer 221 , the active layer 223 , and the second conductivity type semiconductor layer 225 may include a III-V series compound semiconductor, for example, (Al, Ga, In)N and The same nitride-based semiconductor may be included. The first conductivity-type semiconductor layer 221 may include an n-type impurity (eg, Si), and the second conductivity-type semiconductor layer 225 may include a p-type impurity (eg, Mg). have. Also, vice versa. The active layer 223 may include a multiple quantum well structure (MQW), and a composition ratio thereof may be determined to emit light having a desired peak wavelength.

Also, the light emitting structure 220 may include a region in which the second conductivity type semiconductor layer 225 and the active layer 223 are partially removed and the first conductivity type semiconductor layer 221 is partially exposed. For example, as shown in FIG. 1B , the light emitting structure 220 penetrates the second conductivity type semiconductor layer 225 and the active layer 223 to expose the first conductivity type semiconductor layer 221 . It may include a hole 220a. The holes 220a may be formed in plurality, and the shape and arrangement of the holes 220a are not limited to the illustrated ones. Also, in the region where the first conductivity type semiconductor layer 221 is partially exposed, the second conductivity type semiconductor layer 225 and the active layer 223 are partially removed to form the second conductivity type semiconductor layer 225 and the active layer ( 223) may be provided.

In addition, the light emitting structure 220 may further include a roughened surface 220R formed by increasing the roughness of the lower surface thereof. The roughened surface 220R may be formed using at least one method of wet etching, dry etching, and electrochemical etching, for example, an etching method using PEC etching or an etching solution containing KOH and NaOH, etc. It can be formed using Accordingly, the light emitting structure 220 may include protrusions and/or concave portions in a μm to nm scale formed on the surface of the first conductivity type semiconductor layer 221 . Light extraction efficiency of light emitted from the light emitting structure 220 may be improved by the roughened surface 220R.

In addition, the light emitting structure 220 may further include a growth substrate (not shown) positioned under the first conductivity type semiconductor layer 221 . The growth substrate is not limited as long as it is a substrate on which the light emitting structure 220 can be grown. For example, the growth substrate may be a sapphire substrate, a silicon carbide substrate, a silicon substrate, a gallium nitride substrate, an aluminum nitride substrate, or the like. The growth substrate may be separated and removed from the light emitting structure 220 using a known technique.

The second contact electrode 240 is positioned on the second conductivity type semiconductor layer 225 and may be in ohmic contact with the second conductivity type semiconductor layer 225 . In addition, the second contact electrode 240 may at least partially cover the upper surface of the second conductivity-type semiconductor layer 225 , and further, may be disposed to entirely cover the upper surface of the second conductivity-type semiconductor layer 225 . have. In addition, the light emitting structure 220 may be formed to cover the upper surface of the second conductivity type semiconductor layer 225 as a single body in the remaining regions except for the position where the exposed region of the first conductivity type semiconductor layer 221 is formed. Accordingly, by uniformly supplying current to the entire light emitting structure 220, current dispersion efficiency may be improved. However, the present invention is not limited thereto, and the second contact electrode 240 may include a plurality of unit electrodes.

The second contact electrode 240 may be formed of a material capable of making an ohmic contact with the second conductivity type semiconductor layer 225 , and may include, for example, a metallic material and/or a conductive oxide.

When the second contact electrode 240 includes a metallic material, the second contact electrode 240 may include a reflective layer and a cover layer covering the reflective layer. As described above, the second contact electrode 240 may be in ohmic contact with the second conductivity-type semiconductor layer 225 and may function to reflect light. Accordingly, the reflective layer may include a metal capable of forming an ohmic contact with the second conductivity-type semiconductor layer 225 while having high reflectivity. For example, the reflective layer may include at least one of Ni, Pt, Pd, Rh, W, Ti, Al, Mg, Ag, and Au. In addition, the reflective layer may include a single layer or multiple layers.

The cover layer may prevent mutual diffusion between the reflective layer and other materials, and may prevent other materials from diffusing into the reflective layer from damaging the reflective layer. Accordingly, the cover layer may be formed to cover a lower surface and a side surface of the reflective layer. The cover layer may be electrically connected to the second conductivity-type semiconductor layer 225 together with the reflective layer, thereby serving as an electrode together with the reflective layer. The cover layer may include, for example, Au, Ni, Ti, Cr, or the like, and may include a single layer or multiple layers.

The reflective layer and the cover layer may be formed using electron beam deposition, plating, or the like.

Meanwhile, when the second contact electrode 240 includes a conductive oxide, the conductive oxide may be ITO, ZnO, AZO, IZO, or the like. When the second contact electrode 240 includes a conductive oxide, it may cover the upper surface of the second conductive type semiconductor layer 225 having a larger area than when the second contact electrode 240 includes a metal. That is, the separation distance from the edge of the region where the first conductivity-type semiconductor layer 221 is exposed to the second contact electrode 240 may be relatively shorter when the second contact electrode 240 is formed of a conductive oxide. have. In this case, the shortest distance from the portion where the second contact electrode 240 and the second conductivity-type semiconductor layer 225 contact to the portion where the first contact electrode 230 and the first conductivity-type semiconductor layer 221 contact can be relatively shorter, so that the forward voltage (V _f ) of the light emitting device can be reduced.

This may be due to a difference in manufacturing method between a case in which the second contact electrode 240 is formed of a metallic material and a case in which the second contact electrode 240 is formed of a conductive oxide. For example, since the metallic material is formed by deposition or plating, it is formed in a portion spaced apart from the outer edge of the second conductivity-type semiconductor layer 225 by a predetermined distance by the process margin of the mask. On the other hand, after the conductive oxide is entirely formed on the second conductivity-type semiconductor layer 225 , the conductive oxide is removed in the same process in the etching process for exposing the first conductivity-type semiconductor layer 221 . Accordingly, the conductive oxide may be formed relatively closer to the outer edge of the second conductivity-type semiconductor layer 225 . However, the present invention is not limited thereto.

In addition, when the second contact electrode 240 includes ITO, the first insulating layer 250 includes SiO ₂ , and the first contact electrode 230 includes Ag, ITO/SiO ₂ /Ag stack An omnidirectional reflector comprising the structure may be formed.

The insulating layers 250 and 260 partially cover the first and second contact electrodes 230 and 240 , and the first and second contact electrodes 230 and 240 are connected to each other. Insulate. The insulating layers 250 and 260 may include a first insulating layer 250 and a second insulating layer 260 . Hereinafter, the first insulating layer 250 will be described first, and the contents related to the second insulating layer 260 will be described later.

The first insulating layer 250 may partially cover the upper surface of the light emitting structure 220 and the second contact electrode 240 . In addition, the first insulating layer 250 may cover the side surface of the hole 220a and partially expose the first conductivity type semiconductor layer 221 exposed to the hole 220a. The first insulating layer 250 may include an opening positioned in a portion corresponding to the hole 220a and an opening exposing a portion of the second contact electrode 240 . The first conductivity-type semiconductor layer 221 and the second contact electrode 240 may be partially exposed through the openings.

The first insulating layer 250 may include an insulating material, for example, SiO ₂ , SiN _x , MgF ₂ , or the like. Furthermore, the first insulating layer 250 may include multiple layers, and may include a distributed Bragg reflector in which materials having different refractive indices are alternately stacked.

When the second contact electrode 240 includes a conductive oxide, the first insulating layer 250 includes a distributed Bragg reflector to improve luminous efficiency of the light emitting device. In addition, unlike this, the second contact electrode 240 includes a conductive oxide, and by forming the first insulating layer 250 with a transparent insulating oxide (eg, SiO ₂ ), the second contact electrode 240, An omnidirectional reflector formed by the stacked structure of the first insulating layer 250 and the first contact electrode 230 may be formed. In this case, the first contact electrode 230 is preferably formed to almost entirely cover the surface of the first insulating layer 250 except for a region exposing a portion of the second contact electrode 240 . Accordingly, a portion of the first insulating layer 250 may be interposed between the first contact electrode 230 and the second contact electrode 240 .

Furthermore, unlike illustrated, the first insulating layer 250 may further cover at least a portion of the side surface of the light emitting structure 220 . The degree to which the first insulating layer 250 covers the side surface of the light emitting structure 220 may vary depending on whether chip unit isolation is performed in the manufacturing process of the light emitting device. That is, as in the present embodiment, the first insulating layer 250 may be formed to cover only the upper surface of the light emitting structure 220 . In contrast, after individualizing the wafer into chip units in the manufacturing process of the light emitting device, the first insulating layer 250 is When the layer 250 is formed, the first insulating layer 250 may cover the side surface of the light emitting structure 220 .

The first contact electrode 230 may partially cover the light emitting structure 220 . Also, the first contact electrode 230 is in ohmic contact with the first conductive semiconductor layer 221 through the hole 220a and the opening of the first insulating layer 250 positioned at a portion corresponding to the hole 220a. do. In the present exemplary embodiment, the first contact electrode 230 may be formed to entirely cover a portion other than a partial region of the first insulating layer 250 . Accordingly, light may be reflected through the first contact electrode 230 . Also, the first contact electrode 230 may be electrically insulated from the second contact electrode 240 by the first insulating layer 250 .

Since the first contact electrode 230 is formed to entirely cover the upper surface of the light emitting structure 220 except for a partial region, current dissipation efficiency may be further improved. In addition, since the first contact electrode 230 may cover a portion not covered by the second contact electrode 240 , light may be reflected more effectively to improve the luminous efficiency of the light emitting device.

As described above, the first contact electrode 230 may make an ohmic contact with the first conductivity type semiconductor layer 221 and may serve to reflect light. Accordingly, the first contact electrode 230 may include a highly reflective metal layer such as an Al layer. In this case, the first contact electrode 230 may be formed of a single layer or a multilayer. The highly reflective metal layer may be formed on an adhesive layer such as Ti, Cr, or Ni. However, the present invention is not limited thereto, and the first contact electrode 230 may include at least one of Ni, Pt, Pd, Rh, W, Ti, Al, Mg, Ag, and Au.

Also, unlike the drawings, the first contact electrode 230 may be formed to cover the side surface of the light emitting structure 220 . When the first contact electrode 230 is also formed on the side surface of the light emitting structure 220 , the light emitted from the side surface of the active layer 223 is reflected upward to increase the ratio of light emitted to the upper surface of the light emitting device. When the first contact electrode 230 is formed to cover the side surface of the light emitting structure 220 , the first insulating layer 250 may be interposed between the side surface of the light emitting structure 220 and the first contact electrode 230 . have.

Meanwhile, the light emitting device may further include a connection electrode 245 . The connection electrode 245 may be positioned on the second contact electrode 240 , and may be electrically connected to the second contact electrode 240 through the opening of the first insulating layer 250 . Furthermore, the connection electrode 245 may electrically connect the second contact electrode 240 and the second bulk electrode 273 to each other. In addition, the connection electrode 245 may be formed to partially cover the first insulating layer 250 , and may be spaced apart from the first contact electrode 230 to be insulated from each other.

The upper surface of the connection electrode 245 may be formed to have substantially the same height as the upper surface of the first contact electrode 230 . Also, the connection electrode 245 may be formed in the same process as the first contact electrode 230 , and the connection electrode 245 and the first contact electrode 230 may include the same material. However, the present invention is not limited thereto, and the connection electrode 245 and the first contact electrode 230 may include different materials.

The second insulating layer 260 may partially cover the first contact electrode 230 , the first opening 260a partially exposing the first contact electrode 230 , and the second contact electrode 240 . A second opening 260b partially exposed may be included. One or more of the first and second openings 260a and 260b may be formed, respectively.

The second insulating layer 260 may include an insulating material, for example, SiO ₂ , SiN _x , or MgF ₂ . Furthermore, the second insulating layer 260 may include multiple layers, and may include a distributed Bragg reflector in which materials having different refractive indices are alternately stacked. When the second insulating layer 260 is formed of multiple layers, the uppermost layer of the second insulating layer 260 may be formed of SiN _x . Since the uppermost layer of the second insulating layer 260 is formed of SiN _x , it is possible to more effectively prevent moisture from penetrating into the light emitting structure 220 .

The stress buffer layer 265 is disposed on the insulating layers 250 and 260 . In particular, the stress buffer layer 265 may be disposed on the second insulating layer 260 . The stress buffer layer 265 may at least partially cover the upper surface of the second insulating layer 260 , as illustrated. Alternatively, the stress buffer layer 265 may further cover a portion of the side surface of the second insulating layer 260 , and in this case, the stress buffer layer 265 may contact the first contact electrode 230 and the connection electrode 245 . . That is, the stress buffer layer 265 may further cover side surfaces of the first and second openings 260a and 260b.

The stress buffer layer 265 serves to relieve stress generated when the light emitting device is driven. The stress buffer layer 265 may have a relatively large Young's modulus, and thus exhibit a low strain behavior even under high stress. Accordingly, energy is absorbed by the stress buffer layer 265 , so that the light emitting structure 220 , the first and second contact electrodes 230 and 240 , the insulating layers 250 and 260 , and the first and second bulk Stress applied to the electrodes 271 and 273 and the insulating support 280 may be reduced. Stress applied to the other components is relieved by the stress buffer layer 265 , and the mechanical stability of the light emitting device is improved, and the probability of occurrence of cracks and destruction is reduced, thereby improving the reliability of the light emitting device.

Also, the stress buffer layer 265 may have a lower residual stress (generated by a predetermined stress) than the insulating layers 250 and 260 and/or the insulating support 190 . Accordingly, the stress buffer layer 265 may relieve stress applied to the other components due to residual stress in the process of repeatedly turning on/off the light emitting device. In addition, the stress buffer layer 265 may have relatively excellent moisture absorption properties. In particular, the hygroscopicity of the stress buffer layer 265 may be lower than that of the insulating support 280 . Since the stress buffer layer 265 has relatively low hygroscopicity, it is possible to prevent cracks and peeling caused by moisture penetrating into the light emitting device.

In addition, adhesion between the stress buffer layer 265 and the insulating support 280 may be higher than that between the insulating layers 250 and 260 and the insulating support 190 . Therefore, compared to the case in which the insulating support 280 is formed on the second insulating layer 260 , when the insulating support 280 is formed on the stress buffer layer 265 , the probability of separation or delamination at the interface is greatly reduced. .

The stress buffering layer 265 having the above-described effects may include an insulating material that exhibits a stress relaxation behavior and further has an effect of preventing moisture permeation and improving adhesion. For example, the stress buffer layer may include at least one of polyimide, Teflon, benzocyclobutyne (BCB), and parylene. In particular, the stress buffer layer 265 may include a photosensitive material (eg, polyimide), and when the stress buffer layer 265 includes a photosensitive material, the stress buffer layer 265 may be formed only by developing the photosensitive material. can Accordingly, a separate additional patterning process may be omitted, and thus the light emitting device manufacturing process may be simplified. The stress buffer layer 265 may be in contact with the first bulk electrode 271 , the second bulk electrode 273 , and the insulating support 280 .

The thickness of the stress buffer layer 265 is not limited as long as it can obtain an effective stress relaxation behavior and moisture permeation prevention effect, and may have a thickness of, for example, about 2 to 30 μm. However, the present invention is not limited thereto.

The stress buffer layer 265 may be formed through deposition and patterning processes. Furthermore, the stress buffer layer 265 and the second insulating layer 260 may be simultaneously patterned. For example, first, the second insulating layer 260 covering the first contact electrode 230 is formed, and after the stress buffer layer 265 is formed on the second insulating layer 260 , the second insulating layer ( By simultaneously patterning the 260 and the stress buffering layer 265 , the stress buffering layer 265 as shown may be provided. However, the present invention is not limited thereto.

Meanwhile, the stress buffer layer 265 may be omitted.

The first bulk electrode 271 and the second bulk electrode 273 may be positioned on the light emitting structure 220 , and the first bulk electrode 271 and the second bulk electrode 273 are each a first contact electrode ( 230 ) and the second contact electrode 240 may be electrically connected. In particular, the first bulk electrode 271 and the second bulk electrode 273 may be electrically connected to each other by directly contacting the first and second contact electrodes 230 and 240 . In this case, the first bulk electrode 271 and the second bulk electrode 273 may be electrically connected to the first and second contact electrodes 230 and 240 through the first and second openings 260a and 260b, respectively. .

The first bulk electrode 271 includes a protrusion 271a protruding from a side surface where the first and second bulk electrodes 271 and 273 of the first bulk electrode 271 face each other. The second bulk electrode 273 includes a concave portion 273a recessed from a side surface where the first and second bulk electrodes 271 and 273 of the second bulk electrode 273 face each other. The protrusion 271a and the concave portion 273a are included in the first bulk electrode 271 and the second bulk electrode 273, respectively, so that the horizontal cross-sectional area of the first bulk electrode 271 is relatively increased, and the second The horizontal cross-sectional area of the bulk electrode 273 may be relatively reduced. Accordingly, the horizontal cross-sectional area of the first bulk electrode 271 is larger than the horizontal cross-sectional area of the second bulk electrode 273 .

In addition, the imaginary lines D1 - D1 ′ extending along the spaced region where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion. The virtual lines D1 - D1 ′ having at least one or more bent portions may be derived from the shape and arrangement of the protrusion 271a and the concave portion 273b, but the present invention is not limited thereto. The starting point and the ending point of the virtual lines D1-D1' may be located on the same line. That is, as shown, the starting point and the end point of the imaginary line D1-D1' are generally located on a line dividing the light emitting device uniformly into two, but as the imaginary line D1-D1' is bent, the imaginary line D1- A portion of D1 ′ may be positioned to be biased toward the second bulk electrode 273 .

The protrusion 271a and the concave portion 273a may be provided in a form that engages with each other. That is, as shown in FIG. 1, the degree to which the concave portion 273a is concavely depressed and the position of the concave portion 273a may generally correspond to the degree to which the protrusion 271a protrudes and the position of the protrusion 271a, respectively. have. Accordingly, the separation distance between the first bulk electrode 271 and the second bulk electrode 273 may be substantially constant.

Meanwhile, the shapes of the protrusion 271a and the concave portion 273a are not limited to those shown in FIG. 1 . For example, as shown in (a) of FIG. 3 , the width of the protrusion 271b may change according to the protruding direction, and in particular, the width may decrease according to the protruding direction. Corresponding to the protrusion 271b, the width of the concave portion 273b may also change according to the direction in which it is depressed, and its width may decrease according to the direction in which it is depressed. In this case, the imaginary line D2-D2 ′ extending along the spaced region of the portion where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion. In addition, as shown in (b) of FIG. 3 , a plurality of protrusions 271c may be formed, and at least one concave shape corresponding to the protrusion shape of at least some of the protrusions 271c among the plurality of protrusions 271c. A portion 273c may be formed. In this case, the imaginary line D3-D3 ′ extending along the separation region of the portion where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion, and FIG. 3( a ) ) may have more bent portions compared to the embodiment. Also, as shown in FIG. 3C , the width of the protrusion 271d may change according to the protruding direction, and in particular, the width may increase according to the protruding direction. Corresponding to the protrusion 271d, the width of the concave portion 273d may also change according to the direction in which it is depressed, and its width may decrease according to the direction in which it is depressed. In this case, the imaginary line D4-D4 ′ extending along the separation region of the portion where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion. In addition, as shown in (d) of FIG. 3 , the protrusion 271e may be formed in plurality, and at least one of the plurality of protrusions 271e has at least one concave shape corresponding to the protrusion shape of the protrusion 271e. A portion 273e may be formed. The outer shape of the protrusion 271e and the concave portion 273e may be formed in a curved shape. In this case, the imaginary line D5-D5 ′ extending along the separation region of the portion where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion.

However, the present invention is not limited thereto, and the shapes of the protrusion 271a and the concave portion 273a may be variously modified.

Heat is generated when the light emitting device is driven, and the insulating support 280 and the bulk electrodes 271 and 273 have different coefficients of thermal expansion. When this heat is generated, the insulating support 280 and the bulk electrodes 271 and 273 stress is applied to In particular, a relatively greater stress is applied to the region between the first and second bulk electrodes 271 and 273 , and cracks may occur in the insulating support 280 , and the insulating support 280 and the bulk electrodes 271 . , 273) may be separated from each other. When the region between the bulk electrodes 271 and 273 has a linear shape, cracks generated in the insulating support 280 are easily propagated in a straight direction to cause damage to the light emitting device. For example, in a straight imaginary line defined as crossing between the bulk electrodes 271 and 273 , the imaginary line does not overlap the bulk electrodes 271 and 273 , and only the insulating support 280 is the When formed to overlap the imaginary line, cracks generated between the bulk electrodes 271 and 273 are easily propagated along the imaginary line, causing a problem in that the insulating support 280 is separated.

According to the present embodiment, the first bulk electrode 271 includes the protrusion 271a, the second bulk electrode 273 includes the recess 273a, and the first and second bulk electrodes 271 and 273 ), the imaginary lines D1-D1 ′ extending along the spaced region of the opposing portions have at least one bent portion, so that the stress of the insulating support 280 between the bulk electrodes 271 and 273 . increase resistance to Also, even if a crack occurs in the insulating support 280 between the bulk electrodes 271 and 273 , at least one bent portion is formed in the region between the bulk electrodes 271 and 273 so that the crack propagates. can be suppressed. In particular, another imaginary line of a straight line connecting the start point and the end point of the imaginary line D1-D1' overlaps at least a portion of the bulk electrodes 271 and 273, so that the bulk electrode 271 overlaps with another imaginary line of the straight line; 273) blocks the crack from propagating across the insulating support 280. Accordingly, even if cracks occur in the insulating support 280 , it is possible to effectively prevent the insulating support 280 from being separated.

Moreover, the mechanical stability of the insulating support 280 and the bulk electrodes 271 and 273 is increased, and the resistance to stress is improved, so that cracks in the insulating support 280 during the separation of the growth substrate during the light emitting device manufacturing process Alternatively, damage or separation between the insulating support 280 and the bulk electrodes 271 and 273 may be suppressed.

Accordingly, the light emitting device of this embodiment has excellent mechanical stability, and in particular, cracks and damage of the insulating support 280 are prevented, so that a light emitting device having excellent reliability can be provided. Furthermore, according to the structure of the light emitting device of the present embodiment, the probability of occurrence of defects in the light emitting device during the manufacturing process is reduced, and thus the process yield of the light emitting device can be improved.

In addition, since the first bulk electrode 271 includes the protrusion 271a and the horizontal cross-sectional area of the first bulk electrode 271 is greater than the horizontal cross-sectional area of the second bulk electrode 273, the heat dissipation efficiency of the light emitting device This is improved. When the first conductivity-type semiconductor layer 221 is an N-type semiconductor layer, the first bulk electrode 271 may also function as an N-type electrode, and when the light emitting device is driven, light emission and heat generation are generated by the first bulk electrode 271 . It is relatively concentrated in the area in which it is located. Therefore, as in the present embodiment, by forming the horizontal cross-sectional area of the first bulk electrode 271 to be larger than the horizontal cross-sectional area of the second bulk electrode 273, uniform light emission in the entire light-emitting area of the light-emitting device is improved to improve light-emitting characteristics The heat dissipation efficiency of the light emitting device may be improved by effectively dissipating heat through the first bulk electrode 271 . Accordingly, temperature uniformity may be improved by minimizing a temperature difference according to the position of the light emitting structure 220 . The excessive increase of the junction temperature (T _j ) in a specific portion of the light emitting structure 220 is also prevented, thereby preventing a decrease in the efficiency of the light emitting device, thereby improving reliability.

Furthermore, since the separation distance between the first bulk electrode 271 and the second bulk electrode 273 is generally constant, the ratio of the area occupied by the surfaces of the first and second bulk electrodes 271 and 273 to the upper surface of the light emitting device is Reduction by the protrusion 271a and/or the concave portion 273a can be minimized. Accordingly, even when the protrusion 271a and/or the concave portion 273a are formed, heat dissipation efficiency is prevented from being reduced due to a decrease in the horizontal cross-sectional area of the first and second bulk electrodes 271 and 273 .

The first bulk electrode 271 and the second bulk electrode 273 may have a thickness of several tens of μm or more, for example, about 70 to 80 μm. Since the bulk electrodes 271 and 273 have thicknesses in the above-described ranges, the light emitting device itself may be used as a chip scale package.

The first bulk electrode 271 and the second bulk electrode 273 may be formed of a single layer or multiple layers, and may include a material having electrical conductivity. For example, each of the first bulk electrode 271 and the second bulk electrode 273 may include Cu, Pt, Au, Ti, Ni, Al, Ag, or the like. Alternatively, it may include sintered metal particles and a non-metallic material interposed between the metal particles. The first and second bulk electrodes 271 and 273 may be formed using plating, deposition, dotting, or screen printing. Meanwhile, each of the first and second bulk electrodes 271 and 273 may include a first metal layer 271s and a second metal layer 273s. The first metal layer 271s and the second metal layer 273s are positioned below the first and second bulk electrodes 271 and 273, respectively, and the contact electrodes 230 and 240, the insulating layers 250 and 260 and the It may be in contact with the stress buffer layer 265 . The first metal layer 271s and the second metal layer 273s may vary depending on a method of forming the bulk electrodes 271 and 273, and will be described in detail below.

A case in which the first and second bulk electrodes 271 and 273 are formed using plating will be described first. A seed metal is formed on the entire surface of the stress buffer layer 265 , the first opening 260a , and the second opening 260b by a method such as sputtering. The seed metal may include Ti, Cu, Au, Cr, or the like, and the seed metal may serve as an under bump metallization layer (UBM). For example, the seed metal may have a Ti/Cu stacked structure. Next, a mask is formed on the seed metal, wherein the mask masks a portion corresponding to the region where the insulating support 280 is formed, and opens the region where the first and second bulk electrodes 271 and 273 are formed. do. Next, the first and second bulk electrodes 281 are formed by forming the first and second bulk electrodes 271 and 273 in the open region of the mask through a plating process, and then removing the mask and the seed metal through an etching process. , 283) may be provided. In this case, the seed metal remaining under the first and second bulk electrodes 281 and 283 without being removed is formed as the first and second metal layers 271s and 273s.

In addition, the case of forming the first and second bulk electrodes 271 and 273 using the screen printing method is as follows. A UBM layer is formed on at least a portion of the stress buffer layer 265 , the first opening 260a , and the second opening 260b through a deposition and patterning method such as sputtering, or a deposition and lift-off method. The UBM layer may be formed on the region where the first and second bulk electrodes 271 and 273 are to be formed, and may include a (Ti or TiW) layer and a (Cu, Ni, Au single layer or combination) layer. have. For example, the UBM layer may have a Ti/Cu stacked structure. The UBM layer corresponds to the first and second metal layers 271s and 273s. Next, a mask is formed, but the mask masks a portion corresponding to the region where the insulating support 280 is formed, and opens the region where the first and second bulk electrodes 271 and 273 are formed. Next, a material such as Ag paste, Au paste, or Cu paste is formed in the open area through a screen printing process, and the material is cured. Thereafter, the first and second bulk electrodes 271 and 273 may be provided by removing the mask through an etching process.

The insulating support 280 is positioned on the light emitting structure 220 and at least partially covers side surfaces of the bulk electrodes 271 and 273 . The insulating support 280 has electrical insulating properties and covers the side surfaces of the first bulk electrode 271 and the second bulk electrode 273 to effectively insulate them from each other. At the same time, the insulating support 280 may serve to support the first bulk electrode 271 and the second bulk electrode 273 . The insulating support 280 may include, for example, a material such as EMC (Epoxy Molding Compound) or a Si resin. In addition, the insulating support 280 may include light reflective and light scattering particles such as TiO ₂ particles. In particular, when the insulating support 280 includes EMC, as described above, the stress buffer layer 265 prevents the insulating support 280 from being separated and prevents moisture from penetrating into the insulating support 280 . have.

In some embodiments, unlike illustrated, the insulating support 280 may cover the side surface of the light emitting structure 220 , and in this case, the light emission angle of the light emitted from the light emitting structure 220 may vary. For example, when the insulating support 280 further covers at least a portion of the side surface of the light emitting structure 220 , some of the light emitted to the side of the light emitting structure 220 may be reflected to the lower surface of the light emitting structure 220 . . In this way, by adjusting the region in which the insulating support 280 is disposed, the light emitting angle of the light emitting device can be adjusted.

4 and 5 are a plan view and a cross-sectional view for explaining a light emitting device according to another embodiment of the present invention. FIG. 5 is a cross-sectional view of a portion corresponding to the line II-II' of FIG. 4 .

The light emitting device of FIGS. 4 and 5 has a point in which the insulating support 280 includes an upper insulating support 281 and a lower insulating support 283 as compared with the light emitting device of FIGS. 1 and 2, and the light emitting device is a pad There is a difference in that electrodes 291 and 293 are further included. Hereinafter, the light emitting device of the present embodiment will be described with a focus on the differences, and a detailed description of the overlapping configuration will be omitted.

4 and 5, the light emitting device includes a light emitting structure 220, a first contact electrode 230, a second contact electrode 240, insulating layers 250 and 260, first and second bulk electrodes ( 271 and 273 , an insulating support 280 , and first and second pad electrodes 291 and 293 . Furthermore, the light emitting device may further include a growth substrate (not shown), a connection electrode 245 , and a stress buffer layer 265 .

The insulating support 280 is positioned on the light emitting structure 220 and partially covers side surfaces of the bulk electrodes 271 and 273 and upper surfaces of the bulk electrodes 271 and 273 . Also, the insulating support 280 may include openings partially exposing top surfaces of the first bulk electrode 271 and the second bulk electrode 273 . The insulating support 280 may include an upper insulating support 281 and a lower insulating support 283 , and the lower insulating support 283 may surround the side surfaces of the bulk electrodes 271 and 273 , and upper insulating The support 281 may partially cover the upper surfaces of the bulk electrodes 271 and 273 . Also, the upper insulating support 281 may cover the interface between the lower insulating support 283 and the bulk electrodes 271 and 273 .

The insulating support 280 has electrical insulation and covers side surfaces of the first and second bulk electrodes 271 and 273 to effectively insulate them from each other. At the same time, the insulating support 280 may serve to support the first bulk electrode 271 and the second bulk electrode 273 .

The upper surfaces of the bulk electrodes 271 and 273 are partially covered by the upper insulating support 281 so that the exposed area of the upper surfaces of the first and second bulk electrodes 271 and 273 is, respectively, the first bulk electrode ( It may be smaller than the horizontal cross-sectional area of 271 and the horizontal cross-sectional area of the second bulk electrode 273 . In particular, the upper insulating support 281 may be positioned on the upper surfaces of the bulk electrodes 271 and 273 around side surfaces of the first bulk electrode 271 and the second bulk electrode 273 opposite to each other. Accordingly, the separation distance between the upper surface of the first bulk electrode 271 exposed by the opening of the upper insulating support 281 and the exposed upper surface of the second bulk electrode 273 is the first bulk electrode 271 and the second bulk electrode. (273) greater than the separation distance between them.

Specifically, a conductive material (eg, solder, conductive adhesive, eutectic material, etc.) is formed between the exposed upper surfaces 271a and 273a and a separate substrate to form a light emitting device and the By adhering a separate substrate, the light emitting device can be mounted on the separate substrate. In order to prevent an electric short from occurring between the bulk electrodes 271 and 273 due to the conductive material formed for adhesion, the separation distance between the exposed upper surfaces is required to be greater than or equal to a predetermined value. According to the present invention, the insulating support 280 is formed to partially cover the upper surfaces of the bulk electrodes 271 and 273 , thereby exposing the exposed upper surface of the first bulk electrode 271 and the second bulk electrode 273 . The separation distance between the upper surfaces may be greater than the separation distance between the first bulk electrode 271 and the second bulk electrode 273 . Accordingly, the separation distance is formed to be greater than or equal to a predetermined value to prevent an electrical short from occurring between the bulk electrodes 271 and 273 , and at the same time, the separation distance between the bulk electrodes 271 and 273 is between the bulk electrodes 271 . , 273) may be formed below a predetermined value to prevent an electrical short from occurring. Accordingly, it is possible to improve the heat dissipation efficiency of the light emitting device and effectively prevent an electric short from occurring during the mounting process of the light emitting device.

The separation distance between the exposed top surface of the first bulk electrode 271 and the exposed top surface of the second bulk electrode 273 is not limited, but when the light emitting device is mounted on a separate substrate through soldering, the separation distance is about 250 μm or more In addition, when the light emitting device is mounted on a separate substrate through process bonding, the separation distance may be about 80 μm or more. However, the present invention is not limited thereto.

In addition, the upper insulating support 281 includes the bulk electrodes 271 and 273 such that a separation distance between the exposed upper surface of the first bulk electrode 271 and the exposed upper surface of the second bulk electrode 273 is formed to be greater than or equal to a predetermined value. It is sufficient if they are arranged in the upper peripheral region of the side surfaces opposite to each other, and the form arranged in the other regions is not limited. For example, as shown in FIGS. 4 and 5 , the insulating support 280 positioned between the first and second bulk electrodes 271 and 273 may have a 'T' cross-section. Furthermore, the insulating support 280 covering the outer side surfaces of the first and second bulk electrodes 271 and 273 may have a 'L' shape in cross section.

In addition, the insulating support 280 and the bulk electrodes 271 and 273 may be formed of different materials. In particular, the insulating support 280 may include an insulating polymer and/or an insulating ceramic, and the bulk electrodes (271, 273) may include a metallic material. Accordingly, peeling or cracking may occur at the interface between the insulating support 280 and the bulk electrodes 271 and 273 , and damage due to stress and strain that may occur due to bonding of different materials may occur. When the insulating support 280 and/or the bulk electrodes 271 and 273 are damaged, the light emitting structure 220 may be contaminated, and further, cracks may occur in the light emitting structure 220 , so the reliability of the light emitting device This can fall. According to embodiments of the present invention, the insulating support 280 is formed to partially cover the side surfaces of the bulk electrodes 271 and 273 and the upper surfaces of the bulk electrodes 271 and 273, so that the insulating support 280 and Mechanical stability between the bulk electrodes 271 and 273 may be improved. Accordingly, the reliability of the light emitting device may be improved.

In addition, since the mechanical stability of the light emitting device is improved, it is possible to prevent the light emitting structure 220 from being damaged in the process of separating the growth substrate (not shown) from the light emitting structure 220 .

Furthermore, the lower insulating support 283 and the upper insulating support 281 may be formed of the same material or different materials. When the lower insulating support 283 and the upper insulating support 281 are formed of the same material, the insulating support 280 may include, for example, a material such as EMC (Epoxy Molding Compound) or a Si resin. . In addition, the insulating support 280 may include light reflective and light scattering particles such as TiO ₂ particles. When the lower insulating support 283 and the upper insulating support 281 are formed of different materials, the upper insulating support 281 may be formed of a material having low brittleness and/or low hygroscopicity compared to the lower insulating support 283. can For example, the lower insulating support 283 may include a material such as Epoxy Molding Compound (EMC) or Si resin, and the upper insulating support 281 may include a photoresist (PR) and/or a photosolder resist (PSR). It may contain substances such as

Since the upper insulating support 281 is formed of a material having a relatively low brittleness, the probability of cracking or cracking is lower than that of the lower insulating support 283 , and between the lower insulating support 283 and the bulk electrodes 271 and 273 . Penetration of external contaminants through the interface can be prevented. In addition, since the upper insulating support 281 is formed of a material having a relatively low hygroscopicity, it is possible to prevent external contaminants from penetrating through the interface between the lower insulating support 283 and the bulk electrodes 271 and 273 . For example, when the lower insulating support 283 is formed of a material having high hygroscopicity such as EMC, the light emitting device may be more effectively protected from moisture by the upper insulating support 281 formed of a material such as PSR. In particular, when the upper insulating support 281 is formed to cover the interface between the lower insulating support 283 and the bulk electrodes 271 and 273, the above-described light emitting device protection function can be more effectively exhibited.

On the other hand, an area of the exposed upper surface 271a of the first bulk electrode 271 may be smaller than an area of a region where the first bulk electrode 271 and the first contact electrode 230 come into contact, and the second bulk electrode 273 . ), an area of the exposed upper surface 273a may be greater than an area of a region where the second bulk electrode 273 and the second contact electrode 240 contact each other. In this case, the horizontal cross-sectional area of the first bulk electrode 271 may be greater than the horizontal cross-sectional area of the second bulk electrode 273 .

The first pad electrode 291 and the second pad electrode 293 may be positioned on the first bulk electrode 271 and the second bulk electrode 273, respectively, and the first and second bulk electrodes ( Openings of the insulating support 280 partially exposing the upper surfaces of the 271 and 273 may be filled. Accordingly, the first pad electrode 291 and the second pad electrode 293 may cover the exposed upper surface of the first bulk electrode 271 and the exposed upper surface of the second bulk electrode 273 , respectively. Accordingly, the separation distance between the first and second pad electrodes 291 and 293 may correspond to a separation distance between the exposed top surface of the first bulk electrode 271 and the exposed top surface of the second bulk electrode 273 .

Also, as illustrated, upper surfaces of the first pad electrode 291 and the second pad electrode 293 may be positioned flush with the upper surface of the insulating support 280 at substantially the same height. In this case, the upper surface of the light emitting device may be formed to be substantially flat. Also, the top surface of the first pad electrode 291 and the top surface of the second pad electrode 293 may have substantially the same area. Accordingly, the electrical connection portion exposed on the mounting surface of the light emitting device may be formed in the same area, thereby facilitating the mounting process.

The first and second pad electrodes 291 and 293 may be formed using a method such as plating to fill the openings of the insulating support 280 . Thereafter, the first and second pad electrodes 291 and 293 and the insulating support 280 are partially removed using a physical and/or chemical method, for example, lapping or CMP, by using this method to partially remove the first pad electrode ( 291 ) and the upper surface of the second pad electrode 293 may be formed parallel to the upper surface of the insulating support 280 at substantially the same height.

The first pad electrode 291 and the second pad electrode 293 may include a conductive material, particularly, a metallic material, for example, Ni, Pt, Pd, Rh, W, Ti, Al, Au, Sn. , Cu, Ag, Bi, In, Zn, Sb, Mg, Pb, and the like. The first and second pad electrodes 291 and 293 may include substantially the same material as the bulk electrodes 271 and 273 or may be formed of different materials. The first and second pad electrodes 291 and 293 may be formed using a deposition or plating method, for example, may be formed using electroless plating.

Since the light emitting device further includes the first and second pad electrodes 291 and 293, the upper surface of the light emitting device (the light emitting device may be a surface on which the light emitting device is mounted on a separate substrate) may be formed to be substantially flat. Accordingly, a process of mounting the light emitting device on a separate substrate may be facilitated.

6 and 7 are a plan view and a cross-sectional view for explaining a light emitting device according to another embodiment of the present invention. 7 is a cross-sectional view of a portion corresponding to the line III-III' of FIG. 6 .

The light emitting device of FIGS. 6 and 7 is different from the light emitting device of FIGS. 1 and 2 in the structures of the first contact electrode 230 and the insulating layer 255 . Hereinafter, the light emitting device of the present embodiment will be described with a focus on the differences, and detailed descriptions of overlapping components will be omitted below.

6 and 7, the light emitting device includes a light emitting structure 220, a first contact electrode 230, a second contact electrode 240, insulating layers 250 and 260, first and second bulk electrodes ( 271 , 273 ) and an insulating support 280 . Furthermore, the light emitting device may further include a growth substrate (not shown), a connection electrode 245 , and a stress buffer layer 265 .

The light emitting device includes a light emitting structure 220 , wherein the light emitting structure 220 has the first conductivity type semiconductor layer 221 exposed by partially removing the second conductivity type semiconductor layer 225 and the active layer 223 . includes area. As the first conductivity-type semiconductor layer 221 is exposed, the light emitting structure 220 may have a mesa 220m including the second conductivity-type semiconductor layer 225 and the active layer 223 . The location of the mesa 220m is not limited, and for example, as illustrated, the mesa 220m may be at least partially surrounded by the exposed region of the first conductivity-type semiconductor layer 221 .

The first contact electrode 230 may be positioned on a region where the first conductivity-type semiconductor layer 221 is exposed to be in ohmic contact with the first conductivity-type semiconductor layer 221 . In particular, unlike the exemplary embodiment of FIGS. 1 and 2 , the first contact electrode 230 is positioned in a region where the first conductivity-type semiconductor layer 221 is exposed. Accordingly, the first contact electrode 230 and the second contact electrode 240 may be spaced apart from each other.

The insulating layer 255 partially covers the first contact electrode 230 and the second contact electrode 240 , and a first opening partially exposing the first contact electrode 230 and the second contact electrode 240 , respectively. 255a and a second opening 255b. According to the present embodiment, since the first contact electrode 230 is located in the region where the first conductivity-type semiconductor layer 221 is exposed, the insulating layer 255 is formed between the first contact electrode 230 and the second contact electrode ( 240) may not be formed in a sandwiched form. In addition, since the insulating layer 255 may be formed in a single process without being separated into the first insulating layer and the second insulating layer, the manufacturing process of the light emitting device may be further simplified. In particular, when the insulating layer is divided into the first insulating layer and the second insulating layer, a mask pattern forming process for patterning each insulating layer is required at least twice or more. On the other hand, in the present embodiment, the insulating layer 255 is formed of a single insulating layer 255, so that the mask pattern forming process can be omitted at least once.

Meanwhile, the connection electrode 245 may be positioned on the second contact electrode 240 . Also, the side surface of the connection electrode 245 may be covered by the insulating layer 255 . According to the present embodiment, since the insulating layer 255 is formed of a single insulating layer 255 , the connection electrode 245 may be positioned under the insulating layer 255 .

However, in the present embodiment, that the insulating layer 255 is formed of a single insulating layer 255 does not mean that the insulating layer 255 is formed of a single layer, and the insulating layer 255 is formed of multiple layers. can be done

8 and 9 are plan views and cross-sectional views illustrating a light emitting device according to another embodiment of the present invention.

The light emitting device of this embodiment has a different structure of the light emitting structure 220 compared to the light emitting device of FIGS. 1 and 2 , and further includes a wavelength converter 295 and first and second pad electrodes 291 . There is a difference in Accordingly, there is a difference in the mutual structural relationship of the other remaining components, and the following will be described in detail focusing on the difference. A detailed description of the same configuration will be omitted.

8 (a) is a plan view of the light emitting device according to the present embodiment, (b) is a plan view for explaining the position of the hole 220h and the first opening 260a and the second opening 260b. , FIG. 9 is a cross-sectional view showing a cross section of a region corresponding to line IV-IV' in FIGS. 8A and 8B.

8 and 9 , the light emitting device includes a light emitting structure 220 , a first contact electrode 230 , a second contact electrode 240 , insulating layers 250 and 260 , a stress buffer layer 265 , and a first and second bulk electrodes 281 and 283 and an insulating support 190 . Furthermore, the light emitting device may further include a growth substrate (not shown), a wavelength converter 210 , first and second pad electrodes 291 and 293 , and a stress buffer layer 265 .

The light emitting structure 220 may include a region in which the second conductivity type semiconductor layer 225 and the active layer 223 are partially removed and the first conductivity type semiconductor layer 221 is partially exposed. For example, as shown, the light emitting structure 220 has a plurality of holes 220h penetrating through the second conductivity type semiconductor layer 225 and the active layer 223 to expose the first conductivity type semiconductor layer 221 . may include The holes 220h may be positioned generally regularly throughout the light emitting structure 220 . However, the present invention is not limited thereto, and the arrangement shape and number of the holes 220h may be variously modified.

In addition, the shape in which the first conductivity type semiconductor layer 221 is exposed is not limited to the shape of the hole 220h. For example, the exposed region of the first conductivity-type semiconductor layer 221 may be formed in a line shape, a complex shape of a hole and a line, or the like.

The second contact electrode 240 may be positioned on the second conductivity-type semiconductor layer 225 to make an ohmic contact. The second contact electrode 240 may be disposed to entirely cover the upper surface of the second conductivity-type semiconductor layer 225 , and further, may be formed to almost completely cover the upper surface of the second conductivity-type semiconductor layer 225 . have. The second contact electrode 240 may be formed as a single body throughout the light emitting structure 220 . In this case, the second contact electrode 240 may include opening regions corresponding to positions of the plurality of holes 220h. can Accordingly, by uniformly supplying current to the entire light emitting structure 220, current dispersion efficiency may be improved.

However, the present invention is not limited thereto, and the second contact electrode 240 may be formed of a plurality of unit units.

The first insulating layer 250 may partially cover the upper surface of the light emitting structure 220 and the second contact electrode 240 . The first insulating layer 250 may cover side surfaces of the plurality of holes 220h and include openings for partially exposing the first conductivity-type semiconductor layer 221 positioned on the lower surface of the holes 220h. Accordingly, the opening may be positioned to correspond to a position where the plurality of holes 220h are disposed. Also, the first insulating layer 250 may include an opening exposing a portion of the second contact electrode 240 . Furthermore, the first insulating layer 250 may further cover at least a portion of the side surface of the light emitting structure 220 .

The first contact electrode 230 may partially cover the light emitting structure 220 , and through the openings of the holes 220h and the first insulating layer 250 positioned at portions corresponding to the holes 220h , It may be in ohmic contact with the conductive semiconductor layer 221 . Also, unlike the drawings, the first contact electrode 230 may be formed to cover the side surface of the light emitting structure 220 .

The second insulating layer 260 may partially cover the first contact electrode 230 , the first opening 260a partially exposing the first contact electrode 230 , and the second contact electrode 240 . A second opening 260b partially exposed may be included. One or more of the first and second openings 260a and 260b may be formed, respectively. In addition, the openings 260a and 260b may be located at opposite sides of each other to be biased, respectively. The stress buffer layer 265 may be disposed on the second insulating layer 260 .

The first bulk electrode 271 and the second bulk electrode 273 may be positioned on the light emitting structure 220 , and the first bulk electrode 271 and the second bulk electrode 273 are each a first contact electrode ( 230 ) and the second contact electrode 240 may be electrically connected. The insulating support 280 is positioned on the light emitting structure 220 and at least partially covers side surfaces of the bulk electrodes 271 and 273 . Also, the first and second pad electrodes 291 and 293 may be positioned on the first and second bulk electrodes 271 and 273 , respectively. Descriptions of the insulating support 280 and the first and second pad electrodes 291 and 293 are substantially the same as those described with reference to FIGS. 4 and 5 , and thus a detailed description thereof will be omitted.

The wavelength converter 295 may be disposed on the lower surface of the light emitting structure 220 . Light emitted from the light emitting structure 220 by the wavelength conversion unit 210 is wavelength converted to provide a light emitting device capable of realizing light of various colors. In addition, the wavelength conversion unit 210 may be formed to extend not only to the lower surface of the light emitting structure 220 , but also to the side surface of the light emitting structure 220 , and further extend to the side surface of the insulating support 280 . have.

The wavelength conversion unit 295 may include a material capable of converting a wavelength of light. For example, the wavelength conversion unit 295 may be provided in a form in which a phosphor is dispersed in a carrier, or a single crystal phosphor sheet. It may be provided in a form, or may be provided in a form including a quantum dot material. However, the present invention is not limited thereto.

Since the light emitting device includes the wavelength converter 295, a chip scale package capable of emitting white light may be provided.

10 to 25 are plan views and cross-sectional views for explaining a light emitting device and a method of manufacturing the same according to other embodiments of the present invention. In each of the drawings, (a) and (b) included in the same drawing represent a plan view and a cross-sectional view, respectively, and (b) in each figure shows a cross-section of a portion corresponding to the line V-V' of (a) do. In the following description, a light emitting device and a method of manufacturing the same according to various embodiments will be described with reference to FIGS. 10 to 25 . A detailed description of a configuration similar to that described in the embodiments of FIGS. 1 to 9 will be reduced or omitted, and a configuration having a difference will be described in detail. In addition, in the embodiments to be described later, even when a method of manufacturing a light emitting device is described based on a single light emitting device, the configurations and features described in the above embodiments may be applied even when a plurality of light emitting devices are formed.

Referring to FIG. 10 , a light emitting structure 220 including a first conductivity type semiconductor layer 221 , an active layer 223 , and a second conductivity type semiconductor layer 225 is formed on a growth substrate 210 .

The growth substrate 210 is not limited as long as it is a substrate on which the light emitting structure 220 can be grown. For example, the growth substrate 210 may be a sapphire substrate, a silicon carbide substrate, a silicon substrate, a gallium nitride substrate, an aluminum nitride substrate, or the like. The light emitting structure 220 is formed by using a method such as metal-organic chemical vapor deposition (MOCVD), hydride vapor phase epitaxy (HVPE), or molecular beam epitaxy (MBE). can be grown

In addition, although the growth substrate 210 and the light emitting structure 220 corresponding to a single device are illustrated in FIG. 10 , in this embodiment, even when a wafer in which the light emitting structure 220 is grown on the growth substrate 210 is used. Generally the same can be applied.

Then, referring to FIG. 11 , the light emitting structure 220 is patterned to form at least one mesa 220m.

The mesa 220m may be formed by partially removing the second conductivity-type semiconductor layer 225 and the active layer 223 through photolithography and etching processes. As the mesa 220m is formed, the first conductivity-type semiconductor layer 221 may be partially exposed in a region around the mesa 220m. The shape of the mesa 220m is not limited, but, for example, as shown in FIG. 11( a ), may be formed to elongate in substantially the same direction, and may be formed in plurality. In this case, the plurality of mesas 220m are spaced apart from each other.

The present invention is not limited thereto, and as shown in FIGS. 12 (a) and (b), the mesa 220m is integrally formed, and has a form having a portion recessed from one side of the mesa 220m. may have For example, as shown in (a) of FIG. 12 , the mesa 220m ′ is connected to each other at a portion adjacent to one side of the growth substrate 110 , and adjacent to the other side positioned opposite to the one side. The portion may be formed in a form in which a spaced region is formed. The first conductivity-type semiconductor layer 221 may be partially exposed through the separation region. The spaced area may be formed in plurality, and may be formed in two as shown in FIG. 12(a) or in three or more as shown in FIG. 12(b). Alternatively, the mesa 220m may be formed to include a plurality of grooves partially exposing the first conductivity-type semiconductor layer 221 , and in this case, similar to the embodiment of FIGS. 8 and 9 . A light emitting structure 220 in the form of may be provided.

Next, referring to FIG. 13 , the second contact electrode 240 is formed on the second conductivity-type semiconductor layer 225 , that is, on at least a portion of the upper surface of the mesa 220m. Furthermore, a preliminary first insulating layer 251 may be further formed on the light emitting structure 220 .

As described above, the second contact electrode 240 may include at least one of a metal and a conductive oxide. The second contact electrode 240 may be formed to be positioned on at least a portion of the upper surface of the mesa 220m through a known deposition and patterning method.

The preliminary first insulating layer 251 may be formed on the light emitting structure 220 to at least partially cover the upper surface of the light emitting structure 220 except for a region where the second contact electrode 240 is formed. The preliminary first insulating layer 251 may cover a region where the first conductivity type semiconductor layer 221 is exposed, and further cover side surfaces of the mesas 220m, and furthermore, upper surfaces of the mesas 220m. can be partially covered. The preliminary first insulating layer 251 may be in contact with the second contact electrode 240 or may be spaced apart from each other. When the preliminary first insulating layer 251 is spaced apart, the second conductivity-type semiconductor layer 225 is partially exposed between the preliminary first insulating layer 251 and the second contact electrode 240 . The preliminary first insulating layer 251 is SiO ₂ , SiN _x , MgF ₂ and the like. Furthermore, the preliminary first insulating layer 251 may include multiple layers, and may include a distributed Bragg reflector in which materials having different refractive indices are alternately stacked.

Meanwhile, the preliminary first insulating layer 251 may be formed before the formation of the second contact electrode 240 , or may be formed after the formation of the second contact electrode 240 , or of the second contact electrode 240 . It may be formed during formation. For example, when the second contact electrode 240 includes a conductive oxide layer and a reflective layer including a metal positioned on the conductive oxide layer, a conductive oxide layer is formed on the second conductive semiconductor layer 225 , Before forming the reflective layer, a preliminary first insulating layer 251 may be formed. In this case, the conductive oxide layer may be in ohmic contact with the second conductivity type semiconductor layer 225 , and the preliminary first insulating layer 251 may be formed to a thickness of about 1000 Å. In another embodiment, the preliminary first insulating layer 251 may be formed before the formation of the second contact electrode 240 . In this case, the second contact electrode 240 is the second conductivity type semiconductor layer 225 . It forms an ohmic contact and may include a reflective layer formed of a metal material. In these embodiments, by forming the preliminary first insulating layer 251 before the formation of the reflective layer including the metal material, the light reflectance of the reflective layer is reduced and the resistance is increased by material diffusion between the reflective layer and the light emitting structure 220 . can prevent In addition, in the process of forming the reflective layer including the metal material, it is possible to prevent problems such as an electric short that may occur because the metal material remains in other portions where the second contact electrode 240 is not formed.

Next, referring to FIG. 14 , a first insulating layer 250 is formed on the light emitting structure 220 , and the first insulating layer 250 includes the first conductive semiconductor layer 221 , the mesa 220m and the second insulating layer 250 . 2 partially covers the contact electrode 240 . In addition, the first insulating layer 250 has a first opening 250a partially exposing the first conductivity-type semiconductor layer 225 and a second opening 250b partially exposing the second contact electrode 240 . may include

The first insulating layer 250 may include the preliminary first insulating layer 251 and the main first insulating layer 253 described with reference to FIG. 13 . The main first insulating layer 253 may be formed through a known deposition method such as PECVD or E-beam evaporation. At this time, after the main first insulating layer 253 is formed to completely cover the first conductivity-type semiconductor layer 221 , the mesa 220m and the second contact electrode 240 , the first and second openings are formed through a patterning process. By forming 250a and 250b, the first insulating layer 250 as shown can be provided. The patterning process may include a photolithography process or a lift-off process. The main first insulating layer 253 is SiO ₂ , SiN _x , MgF ₂ and the like. Furthermore, the main first insulating layer 253 may include multiple layers, and may include a distributed Bragg reflector in which materials having different refractive indices are alternately stacked. Also, the main first insulating layer 253 may have a greater thickness than the preliminary first insulating layer 251 .

At least one first opening 250a may be formed, for example, on each of the mesas 220m. Also, the first opening 250a may be formed at a position adjacent to one side of the growth substrate 210 . The second opening 250b may be formed to have an elongated shape along the direction in which the mesa 220m extends. In particular, the second opening 250b may be formed adjacent to long sides of the mesa 220m. However, the positions, sizes, and numbers of the first and second openings 250a and 250b are not limited thereto, and may be variously modified according to positions where the bulk electrodes 271 and 273, which will be described later, are formed.

Meanwhile, in the present embodiment, the second contact electrode 230 is formed after the mesa 220m is formed, but unlike this, the mesa 220m is formed after the second contact electrode 230 is first formed. can also be formed.

Next, referring to FIG. 15 , a first contact electrode 230 is formed on the first insulating layer 250 . The first contact electrode 230 may be in ohmic contact with the first conductivity-type semiconductor layer 221 exposed through the first opening 250a. Furthermore, a connection electrode 245 electrically contacting the second contact electrode 240 through the second opening 250b may be further formed.

The first contact electrode 230 and the connection electrode 245 may be formed through a known deposition and patterning method, may be formed simultaneously, or may be formed through a separate process. The first contact electrode 230 and the connection electrode 245 may be formed of the same material and a multi-layer structure, or may be formed of a different material and/or a multi-layer structure. The first contact electrode 230 and the connection electrode 245 are spaced apart from each other, and accordingly, the first contact electrode 230 and the second contact electrode 240 are electrically insulated from each other.

For example, each of the first contact electrode 230 and/or the connection electrode 245 may include a multilayer structure. The multilayer structure may have a laminated structure of a first adhesive layer (ohmic contact layer)/reflective layer/barrier layer/anti-oxidation layer/second adhesive layer. The first contact layer contacts the first conductivity-type semiconductor layer 221 and/or the second contact electrode 240 , and may include Ni, Ti, Cr, or the like. The reflective layer may include a metal having a high light reflectance, for example, Al, Ag, or the like. The barrier layer prevents the metal of the reflective layer from inter-diffusion, and may be formed as a single layer of Cr, Co, Ni, Pt, or TiN, or as a multilayer together with Ti, Mo, or W, for example, Cr/Ti. may have a multi-layer structure of The anti-oxidation layer prevents oxidation of other layers positioned below the anti-oxidation layer, and may include a metal material with strong resistance to oxidation. The antioxidant layer may include, for example, Au, Pt, Ag, or the like. The second adhesive layer may be employed to improve bonding strength between the second insulating layer 260 and the first conductive semiconductor layer 221 (or the second insulating layer 260 and the connection electrode 245), For example, it may include Ti, Ni, Cr, and the like. However, the present invention is not limited thereto.

Alternatively, the connection electrode 245 may be omitted. 16 , when the connection electrode 245 is omitted, the second contact electrode 240 is exposed through the second opening 250b. Accordingly, in this case, the second bulk electrode 173 may directly contact the second contact electrode 240 .

Then, referring to FIG. 17 , a second insulating layer 260 partially covering the first contact electrode 230 and the connection electrode 245 is formed. The second insulating layer 260 may include a third opening 260a and a fourth opening 260b exposing the first contact electrode 230 and the connection electrode 245 , respectively. Furthermore, a stress buffer layer 265 may be further formed on the second insulating layer 260 .

The second insulating layer 260 may be formed through a known deposition method such as PECVD or E-beam evaporation. In this case, the second insulating layer 260 is formed to completely cover the first contact electrode 230 and the connection electrode 245 , and then the third and fourth openings 260a and 260b are formed through a patterning process. A second insulating layer 260 as described above may be provided. The patterning process may include a photolithography process or a lift-off process. The second insulating layer 260 is SiO ₂ , SiN _x , MgF ₂ and the like. Furthermore, the second insulating layer 260 may include multiple layers, and may include a distributed Bragg reflector in which materials having different refractive indices are alternately stacked. The uppermost layer of the second insulating layer 260 may be formed of SiN _x . Since the uppermost layer of the second insulating layer 260 is formed of SiN _x , it is possible to more effectively prevent moisture from penetrating into the light emitting structure 220 . In addition, the second insulating layer 260 may have a thinner thickness than the first insulating layer 250 , and may have a thickness of about 0.8 μm or more in order to secure dielectric breakdown voltage. However, the present invention is not limited thereto.

The third and fourth openings 260a and 260b expose the first contact electrode 230 and the connection electrode 245 , respectively, so that the bulk electrodes 171 and 173 are connected to the first contact electrode 230 and the second contact. A path that can be electrically connected to the electrode 240 may be provided.

The stress buffer layer 265 may be formed through a method such as deposition or spin coating, and may be patterned simultaneously with the second insulating layer 260 . Accordingly, the stress buffer layer 265 may include openings formed at positions corresponding to the third and fourth openings 260a and 260b.

18 and 19 , a first bulk electrode 171 , a second bulk electrode 173 , and a lower insulating support 183 are formed on the second insulating layer 260 .

Specifically, referring to FIG. 18 , regions in which the first and second bulk electrodes 271 and 273 are formed are defined using the mold 310 for forming the bulk electrode, and the first and second bulk electrodes 271 and 271 are defined. A bulk electrode 273 may be formed. The mold 310 for forming the bulk electrode may be a patternable mold, and may include, for example, photosensitive polyimide, SU-8, photoresist for plating, or a dry film.

The first and second bulk electrodes 271 and 273 may be formed using plating, deposition, dotting, or screen printing. Meanwhile, forming the first and second bulk electrodes 271 and 273 may include forming the first metal layer 271s and the second metal layer 273s. The first metal layer 271s and the second metal layer 273s are respectively positioned under the first and second bulk electrodes 271 and 273 , and include the first contact electrode 230 , the connection electrode 245 , and the insulating layers. (250, 260) and the stress buffer layer 265 may be in contact. The first metal layer 271s and the second metal layer 273s may vary according to a method of forming the bulk electrodes 271 and 273 .

Next, referring to FIG. 19 , the mold 310 for forming the bulk electrode is removed, and a lower insulating support 283 that at least partially covers the side surfaces of the first and second bulk electrodes 271 and 273 is formed. The lower insulating support 283 may be provided by, for example, forming a material such as EMC (Epoxy Molding Compound) or a Si resin through a known method such as screen printing or spin coating.

The light emitting device manufacturing method of this embodiment may further include planarizing the upper surfaces of the first bulk electrode 271 , the second bulk electrode 273 and the lower insulating support 283 after the lower insulating support 283 is formed. have. Accordingly, upper surfaces of the first bulk electrode 271 , the second bulk electrode 273 , and the lower insulating support 283 may be formed to be substantially flush. The planarization of the first bulk electrode 271 , the second bulk electrode 273 , and the lower insulating support 283 may include using at least one of grinding, lapping, CMP, and wet etching.

Hereinafter, the formation of the first bulk electrode 271 , the second bulk electrode 273 , and the lower insulating support 283 will be described in more detail. When the first and second bulk electrodes 271 and 273 are formed using plating, the first and second bulk electrodes 271 and 273 are formed on the entire surface of the stress buffer layer 265 , the third opening 260a and the fourth opening 260b by a method such as sputtering. and second metal layers 271s and 273s are formed. The first and second metal layers 271s and 273s may include Ti, Cu, Au, Cr, or the like, and the first and second metal layers 271s and 273s may include an under bump metallization layer (UBM) or a seed medallion. can play the same role. For example, the first and second metal layers 271s and 273s may have a Ti/Cu stack structure. Then, a mask is formed on the first and second metal layers 271s and 273s, and the mask may be a mold 310 for forming a bulk electrode. The mold 310 for forming the bulk electrode masks a portion corresponding to the region where the lower insulating support 283 is formed, and opens the region where the first and second bulk electrodes 271 and 273 are formed. Next, first and second bulk electrodes 271 and 273 are formed in the open region of the mask through a plating process, and the first and second bulk electrodes 271 and 273 are formed of the first and second metal layers 271s, respectively. , 273s) may be formed as a seed. Thereafter, the first and second parts of the first and second bulk electrodes 271 and 273 positioned under the mold 310 for forming the bulk electrode and the mold 310 for forming the bulk electrode are removed through an etching process. Bulk electrodes 271 and 273 may be provided. Accordingly, the first and second metal layers 271s and 273s may remain under the first and second bulk electrodes 281 and 283 .

In addition, the case of forming the first and second bulk electrodes 271 and 273 using the screen printing method is as follows. A UBM layer is formed on at least a portion of the stress buffer layer 265 , the third opening 260a , and the fourth opening 260b through a deposition and patterning method such as sputtering, or a deposition and lift-off method. The UBM layer may be formed on the region where the first and second bulk electrodes 271 and 273 are to be formed, and may include a (Ti or TiW) layer and a (Cu, Ni, Au single layer or combination) layer. have. For example, the UBM layer may have a Ti/Cu stacked structure. The UBM layer may correspond to the first and second metal layers 271s and 273s. Next, a mask is formed, but the mask masks a portion corresponding to the region where the lower insulating support 283 is formed, and opens the region where the first and second bulk electrodes 271 and 273 are formed. Next, a material such as Ag paste, Au paste, or Cu paste is formed in the open area through a screen printing process, and the material is cured. Thereafter, the first and second bulk electrodes 271 and 273 may be provided by removing the mask through an etching process.

The first bulk electrode 271 includes a first protrusion 271a protruding from a side surface where the first and second bulk electrodes 271 and 273 of the first bulk electrode 271 face each other, and the first It includes a second protrusion 271b that further protrudes from the protrusion 271a toward the second bulk electrode 273 . The second bulk electrode 273 includes a first concave portion 273a in which the first and second bulk electrodes 271 and 273 are depressed from opposite sides to each other, and the first concave portion 273a is recessed from the first concave portion 273a. and a second concave portion 273b. Accordingly, the horizontal cross-sectional area of the first bulk electrode 171 may be greater than the horizontal cross-sectional area of the second bulk electrode 173 .

In addition, the protrusions 271a and 271b and the concave portions 273a and 273b may be formed to generally engage with each other. The first protrusion 271a may be positioned to correspond to the portion recessed by the first concave portion 273a , and the second protrusion 271b may be positioned to correspond to the portion recessed by the second concave portion 273b . can do. Accordingly, the separation distance between the side surfaces of the first bulk electrode 271 and the second bulk electrode 273 facing each other may be maintained substantially constant. Furthermore, the width of the second protrusion 271b may be smaller than the width of the first protrusion 271a.

The second protrusion 271b may have various shapes, and the second protrusion 271b is a polygon having an inscribed circle 200ic having a diameter of about 50 μm or more and about 150 μm or less with the central point 200c of the light emitting device as the origin; It may be formed in at least a part of a circle or an ellipse. For example, as illustrated, the second protrusion 271b may have a shape including an arc corresponding to the inscribed circle 200ic having the central portion 200c of the light emitting device as the origin. The shapes of the first and second concave portions 273a and 273b may be formed to correspond to the shapes of the first and second protrusions 271a and 271b.

The imaginary line D6-D6 ′ extending along a separation region of a portion where the first and second bulk electrodes 271 and 273 face each other may have at least one bent portion. The imaginary line D6-D6' having at least one bent portion may be derived from the shape and arrangement of the protrusions 271a and 271b and the concave portions 273a and 273b, but the present invention is not limited thereto. not. The starting point and the ending point of the virtual line D6-D6' may be located on the same line.

On the other hand, the protrusions 271a and 271b of the first bulk electrode 271 may be located at positions overlapping the central portion 200c of the light emitting device in the vertical direction. In particular, in this embodiment, the second protrusion 271b is formed as at least a part of a polygonal, circular or elliptical shape in contact with an inscribed circle 200ic having the central portion 200c of the light emitting device as the origin, and the central portion 200c of the light emitting device. and are positioned vertically overlapping with each other. Accordingly, it is possible to prevent cracks or damage to the insulating support 280 in the light emitting device manufacturing process, thereby improving the manufacturing yield of the light emitting device. In this regard, it will be described later in more detail. In addition, the protrusions 271a and 271b vertically overlap the central portion 200c of the light emitting device, thereby effectively preventing cracks and breakage of the insulating support 280 . Accordingly, it is possible to improve the strength of the light emitting device with respect to external impact, it is possible to further improve the strength against the bending momentum due to externally applied stress. In particular, since the vertical peripheral region of the central portion 200c of the light emitting device is covered by the first bulk electrode 271 by the second protrusion 271b, the mechanical stability of the light emitting device can be more effectively improved.

Next, referring to FIG. 20 , a first pad electrode 291 , a second pad electrode 293 and an upper insulating support 281 are further formed on the lower insulating support 283 and the bulk electrodes 271 and 273 . can do.

The first and second pad electrodes 291 and 293 may be formed on the first and second bulk electrodes 271 and 273 through deposition and patterning processes, respectively. The upper insulating support 281 may surround side surfaces of the first and second pad electrodes 291 and 293 . By forming the upper insulating support 281 , the insulating support 280 including the upper insulating support 281 and the lower insulating support 283 may be provided. The upper insulating support 281 may be formed of the same material as the lower insulating support 283 , or may be formed of a different material.

Next, referring to FIG. 21 , the growth substrate 210 may be separated from the light emitting structure 220 . The growth substrate 210 may be separated and removed from the first conductivity type semiconductor layer 221 using at least one of laser lift-off, chemical lift-off, thermal lift-off, and stress lift-off. After the growth substrate 210 is separated, the growth substrate 210 is separated and exposed through at least one of a dry etching method, a wet etching method, a physical method, a chemical method, and a physicochemical method. The surface may be partially removed.

Meanwhile, before removing the growth substrate 210 , a temporary substrate (not shown) may be bonded to the opposite side of the growth substrate 210 . In the process of separating the growth substrate 210 , the temporary substrate serves to support the light emitting device. Accordingly, it is possible to suppress the occurrence of defects in the light emitting device due to stress and strain generated while the growth substrate 210 is separated. In particular, when a large-area growth substrate is separated on a wafer-by-wafer basis to manufacture a plurality of light emitting devices, cracks or damage occurs in the light emitting structure 220 during the separation process of the growth substrate 210, so that the failure of the light emitting device is highly unlikely. high. The temporary substrate can prevent the failure of the light emitting device in this case, in particular. For example, as shown in FIG. 22 , a temporary substrate 320 may be applied when a plurality of light emitting devices are manufactured.

In the case of manufacturing a plurality of light emitting devices on a wafer basis, after the growth substrate 210 is separated, a portion between the unit device regions may be partially removed. As shown in FIG. 22A , when manufacturing a plurality of light emitting devices, the wafer W1 from which the growth substrate 210 is separated may be positioned on the temporary substrate 320 . In this case, the wafer W1 may include a plurality of unit devices UD, and a boundary L1 between the plurality of unit devices UD may be defined as a division region 331 . As shown in FIG. 22B , the divided region 331 may be partially removed to form a division groove 333 between the plurality of unit devices UD. The division groove 333 may be formed by at least partially removing the first conductivity-type semiconductor layer 221 through a method such as dry etching. Before dividing the wafer W1 into unit light emitting devices, by forming the division groove 333 in which the first conductivity type semiconductor layer 221 is partially removed, light emission is generated in the process of dividing the wafer W1 into unit light emitting devices. It is possible to prevent chipping or cracks from occurring in the structure 220 . However, the process of forming the division groove 333 may be omitted.

Then, referring to FIG. 23 , a wavelength conversion unit 295 may be formed on the light emitting structure 220 . In addition, before forming the wavelength converter 295, the roughness of the surface of the light emitting structure 220 may be increased to further form a roughened surface 220R. Accordingly, a light emitting device as shown in FIG. 23 may be provided.

The wavelength conversion unit 295 may include a material capable of converting a wavelength of light. For example, the wavelength conversion unit 295 may be provided in a form in which a phosphor is dispersed in a carrier, or a single crystal phosphor sheet. It may be provided in a form, or may be provided in a form including a quantum dot material. However, the present invention is not limited thereto. Since the light emitting device of the present embodiment includes the wavelength converter 295, a chip scale package capable of emitting white light may be provided. The wavelength conversion unit 295 may be formed to extend not only to the upper surface of the light emitting structure 220 , but also to the side surface of the light emitting structure 220 , and further extend to the side surface of the insulating support 280 . The wavelength conversion unit 295 may be formed through a coating and curing method, may be formed through a spray method, or may be formed through other known methods.

The roughened surface 220R may be formed using at least one method of wet etching, dry etching, and electrochemical etching, for example, an etching method using PEC etching or an etching solution containing KOH and NaOH, etc. It can be formed using Accordingly, the light emitting structure 220 may include protrusions and/or concave portions in a μm to nm scale formed on the surface of the first conductivity type semiconductor layer 221 . Light extraction efficiency of light emitted from the light emitting structure 220 may be improved by the roughened surface 220R.

On the other hand, after the formation of the wavelength conversion unit 295, a passivation layer (not shown) that at least partially covers the surface of the light emitting device may be further formed.

Meanwhile, the light emitting device illustrated in FIG. 23 may be manufactured from a wafer W2 including a plurality of unit devices UD. 24 and 25 , as shown in FIG. 24A , a wafer W2 including a plurality of unit devices UD bonded to a temporary substrate 320 is prepared, and the wafer W2 ) may be located on the first support 340 for the division process. The first support 340 may include a dicing tape. Next, referring to FIG. 24B , the temporary substrate 320 is separated from the wafer W2 , and the wafer W2 is diced along the dividing line L2 . The dividing line L2 corresponds to a boundary between the plurality of unit elements UD. Next, the plurality of separated unit elements UD may be picked up and transferred from the first support 340 to the second support 340a in order to proceed with the next process. The second support 340a may also include a dicing tape. At this time, as shown in FIG. 24(c) , when the second support 340a is a dicing tape, picking up the unit element UD1 is the lower portion of the dicing tape (the second support 340a). may include pushing the one unit element UD1 upwards using an ejector pin 350 in FIG.

In this process, the ejector pin 350 applies an impact to a portion of the lower portion of the light emitting device. As shown in FIGS. 24( c ) and 25 , stress may propagate along the vertical direction C1 from the portion PP to which an impact is applied by the pin point of the ejector pin 350 . Accordingly, stress may be concentrated on the portion PP to which the impact is applied by the pin point of the ejector pin 350 and the regions overlapping the vertical direction C1 thereof. In this case, the portion PP to which the impact is applied by the pinpoint may substantially coincide with the central portion 200c of the light emitting device. When the insulating support 280 is positioned at a portion overlapping the central portion 200c of the light emitting device in the vertical direction C1 , in particular, between the first and second bulk electrodes 271 and 273 among the insulating support 280 . When the portion located in the light emitting device overlaps with the central portion 200c of the light emitting device in the vertical direction C1, cracks may easily occur in the insulating support 280, thereby causing defects in the manufactured light emitting device. According to the present embodiment, as shown in (a) and (b) of Fig. 25, the central portion 200c of the light emitting device, which generally corresponds to the portion PP that is impacted by the pinpoint) and the vertical direction (C1) ), the first bulk electrode 271 , in particular, the protrusions 271a and 271b are positioned at the overlapping portion, thereby effectively preventing the failure of the insulating support 280 due to the ejector pin 350 . In addition, when the second protrusion 271b is formed in a polygonal, circular or oval shape having an inscribed circle 200ic having a diameter of about 50 μm or more with the central portion 200c of the light emitting device as the origin, the ejector pin 350 impacts By absorbing and alleviating the stress generated by the , it is possible to more effectively prevent a defect from occurring due to the stress being applied to the insulating support 280 .

In addition, according to the present embodiment, similarly to the other embodiments described above, a light emitting device having excellent mechanical stability and high heat dissipation efficiency may be provided.

26 is an exploded perspective view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a lighting device.

Referring to FIG. 26 , the lighting device according to the present embodiment includes a diffusion cover 1010 , a light emitting device module 1020 , and a body portion 1030 . The body 1030 may accommodate the light emitting device module 1020 , and the diffusion cover 1010 may be disposed on the body 1030 to cover the upper portion of the light emitting device module 1020 .

The body portion 1030 is not limited as long as it can accommodate and support the light emitting device module 1020 and supply electrical power to the light emitting device module 1020 . For example, as illustrated, the body 1030 may include a body case 1031 , a power supply device 1033 , a power case 1035 , and a power connection unit 1037 .

The power supply device 1033 is accommodated in the power case 1035 and electrically connected to the light emitting device module 1020, and may include at least one IC chip. The IC chip may adjust, convert, or control characteristics of power supplied to the light emitting device module 1020 . The power case 1035 may receive and support the power supply 1033 , and the power case 1035 to which the power supply 1033 is fixed therein may be located inside the body case 1031 . . The power connection unit 115 may be disposed at the lower end of the power case 1035 to be coupled to the power case 1035 . Accordingly, the power connection unit 115 may be electrically connected to the power supply device 1033 inside the power case 1035 , and may serve as a passage through which external power may be supplied to the power supply device 1033 .

The light emitting device module 1020 includes a substrate 1023 and a light emitting device 1021 disposed on the substrate 1023 . The light emitting device module 1020 may be provided on the body case 1031 and electrically connected to the power supply 1033 .

The substrate 1023 is not limited as long as it is a substrate capable of supporting the light emitting device 1021 , and may be, for example, a printed circuit board including wiring. The substrate 1023 may have a shape corresponding to the fixing portion of the upper portion of the body case 1031 so as to be stably fixed to the body case 1031 . The light emitting device 1021 may include at least one of the light emitting devices according to the above-described embodiments of the present invention.

The diffusion cover 1010 may be disposed on the light emitting device 1021 , and may be fixed to the body case 1031 to cover the light emitting device 1021 . The diffusion cover 1010 may have a light-transmitting material, and by adjusting the shape and light transmittance of the diffusion cover 1010 , the directivity characteristics of the lighting device may be adjusted. Accordingly, the diffusion cover 1010 may be modified in various forms according to the purpose of use of the lighting device and the application aspect.

27 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a display device.

The display device of the present embodiment includes a display panel 2110 , a backlight unit BLU1 providing light to the display panel 2110 , and a panel guide 2100 supporting a lower edge of the display panel 2110 .

The display panel 2110 is not particularly limited and may be, for example, a liquid crystal display panel including a liquid crystal layer. A gate driving PCB for supplying a driving signal to the gate line may be further positioned at an edge of the display panel 2110 . Here, the gate driving PCBs 2112 and 2113 are not formed on a separate PCB, but may be formed on a thin film transistor substrate.

The backlight unit BLU1 includes a light source module including at least one substrate 2150 and a plurality of light emitting devices 2160 . Furthermore, the backlight unit BLU1 may further include a bottom cover 2180 , a reflective sheet 2170 , a diffusion plate 2131 , and optical sheets 2130 .

The bottom cover 2180 is opened upward to accommodate the substrate 2150 , the light emitting device 2160 , the reflective sheet 2170 , the diffusion plate 2131 , and the optical sheets 2130 . Also, the bottom cover 2180 may be coupled to the panel guide 2100 . The substrate 2150 may be disposed under the reflective sheet 2170 to be surrounded by the reflective sheet 2170 . However, the present invention is not limited thereto, and when the reflective material is coated on the surface, it may be positioned on the reflective sheet 2170 . In addition, a plurality of substrates 2150 may be formed so that the plurality of substrates 2150 are arranged side by side, but is not limited thereto, and may be formed of a single substrate 2150 .

The light emitting device 2160 may include at least one of the light emitting devices according to the above-described embodiments of the present invention. The light emitting devices 2160 may be regularly arranged in a predetermined pattern on the substrate 2150 . In addition, a lens 2210 may be disposed on each light emitting device 2160 to improve uniformity of light emitted from the plurality of light emitting devices 2160 .

The diffusion plate 2131 and the optical sheets 2130 are positioned on the light emitting device 2160 . The light emitted from the light emitting device 2160 may be supplied to the display panel 2110 in the form of a surface light source through the diffusion plate 2131 and the optical sheets 2130 .

In this way, the light emitting device according to the embodiments of the present invention can be applied to the direct type display device as in the present embodiment.

28 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment is applied to a display device.

The display device provided with the backlight unit according to the present embodiment includes a display panel 3210 on which an image is displayed, and a backlight unit BLU2 disposed on the rear surface of the display panel 3210 to irradiate light. Furthermore, the display device includes a frame 240 supporting the display panel 3210 and accommodating the backlight unit BLU2 , and covers 3240 and 3280 surrounding the display panel 3210 .

The display panel 3210 is not particularly limited and may be, for example, a liquid crystal display panel including a liquid crystal layer. A gate driving PCB for supplying a driving signal to the gate line may be further positioned at an edge of the display panel 3210 . Here, the gate driving PCB is not formed on a separate PCB, but may be formed on the thin film transistor substrate. The display panel 3210 is fixed by covers 3240 and 3280 positioned at upper and lower portions thereof, and the lower cover 3280 may be coupled to the backlight unit BLU2 .

The backlight unit BLU2 providing light to the display panel 3210 includes a lower cover 3270 having a partially opened upper surface, a light source module disposed on one side of the inner side of the lower cover 3270, and positioned in parallel with the light source module. and a light guide plate 3250 for converting point light into surface light. In addition, the backlight unit BLU2 of the present embodiment is disposed on the light guide plate 3250 and the optical sheets 3230 for diffusing and condensing light are disposed under the light guide plate 3250 and proceeds in the lower direction of the light guide plate 3250 . It may further include a reflective sheet 3260 for reflecting the light to the display panel 3210 direction.

The light source module includes a substrate 3220 and a plurality of light emitting devices 3110 spaced apart from each other at regular intervals on one surface of the substrate 3220 . The substrate 3220 is not limited as long as it supports the light emitting device 3110 and is electrically connected to the light emitting device 3110 , and may be, for example, a printed circuit board. The light emitting device 3110 may include at least one light emitting device according to the above-described embodiments of the present invention. Light emitted from the light source module is incident on the light guide plate 3250 and is supplied to the display panel 3210 through the optical sheets 3230 . Through the light guide plate 3250 and the optical sheets 3230 , the point light source emitted from the light emitting devices 3110 may be transformed into a surface light source.

In this way, the light emitting device according to the embodiments of the present invention can be applied to the edge-type display device as in the present embodiment.

29 is a cross-sectional view illustrating an example in which a light emitting device according to an embodiment of the present invention is applied to a head lamp.

Referring to FIG. 29 , the head lamp includes a lamp body 4070 , a substrate 4020 , a light emitting device 4010 , and a cover lens 4050 . Furthermore, the head lamp may further include a heat dissipation unit 4030 , a support rack 4060 , and a connection member 4040 .

The substrate 4020 is fixed by the support rack 4060 and spaced apart from the lamp body 4070 . The substrate 4020 is not limited as long as it is a substrate capable of supporting the light emitting device 4010 , and may be, for example, a substrate having a conductive pattern such as a printed circuit board. The light emitting device 4010 is positioned on the substrate 4020 , and may be supported and fixed by the substrate 4020 . In addition, the light emitting device 4010 may be electrically connected to an external power source through the conductive pattern of the substrate 4020 . In addition, the light emitting device 4010 may include at least one light emitting device according to the above-described embodiments of the present invention.

The cover lens 4050 is positioned on a path through which light emitted from the light emitting device 4010 travels. For example, as shown, the cover lens 4050 may be disposed to be spaced apart from the light emitting device 4010 by the connecting member 4040 , and may be disposed in a direction to provide light emitted from the light emitting device 4010 . can A beam angle and/or color of light emitted from the headlamp to the outside may be adjusted by the cover lens 4050 . Meanwhile, the connection member 4040 may serve as a light guide for fixing the cover lens 4050 to the substrate 4020 and also surrounding the light emitting device 4010 to provide a light emitting path 4045 . In this case, the connection member 4040 may be formed of a light reflective material or coated with a light reflective material. Meanwhile, the heat dissipation unit 4030 may include a heat dissipation fin 4031 and/or a heat dissipation fan 4033 , and radiates heat generated when the light emitting device 4010 is driven to the outside.

In this way, the light emitting device according to the embodiments of the present invention may be applied to the head lamp according to the present embodiment, in particular, a vehicle head lamp.

In the above, various embodiments of the present invention have been described, but the present invention is not limited to each of the above-described embodiments and features. The invention changed through combination and substitution of technical features described in the embodiments is also included in the scope of the present invention, and various modifications and changes are possible within the scope without departing from the technical spirit of the claims of the present invention.

Claims (23)

a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer;
first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively;
a connection electrode positioned on the second contact electrode;
an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes;
a stress buffer layer positioned on the insulating layer;
first and second bulk electrodes disposed on the light emitting structure and the stress buffer layer and electrically connected to the first and second contact electrodes, respectively; and
an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes;
the insulating layer includes a first opening and a second opening exposing the first contact electrode and the connection electrode, respectively;
The first bulk electrode includes a protrusion protruding from a side surface of the first and second bulk electrodes facing each other,
The second bulk electrode may include a concave portion recessed from a side surface of the first and second bulk electrodes facing each other.
The method according to claim 1,
The protrusion is a light emitting element engaged with the concave portion.
The method according to claim 1,
A light emitting device in which the width of the protrusion varies along the protruding direction.
4. The method according to claim 3,
A width of the protrusion decreases along a protruding direction, and a width of the concave portion decreases along a recessed direction.
The method according to claim 1,
A light emitting device in which each of the protrusions and the concave portions is formed in plurality, and the plurality of protrusions engage the plurality of concave portions.
a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer;
first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively;
an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes;
a stress buffer layer positioned on the insulating layer;
first and second bulk electrodes disposed on the light emitting structure and the stress buffer layer and electrically connected to the first and second contact electrodes, respectively; and
an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes;
The first bulk electrode includes a protrusion protruding from a side surface of the first and second bulk electrodes facing each other,
The second bulk electrode includes a concave portion recessed from a side surface of the first and second bulk electrodes facing each other,
The insulating layer includes a first insulating layer and a second insulating layer,
the first insulating layer includes a first opening and a second opening partially covering the second contact electrode and partially exposing the first conductivity-type semiconductor layer and the second contact electrode, respectively;
the first contact electrode partially covers the first insulating layer;
and the second insulating layer partially covers the first contact electrode, and includes a third opening and a fourth opening partially exposing the first contact electrode and the second contact electrode.
7. The method of claim 6,
The light emitting device further comprising a connection electrode positioned between the second contact electrode and the second bulk electrode, wherein the connection electrode is formed of the same material as the first contact electrode.
7. The method of claim 6,
A portion of the first insulating layer is interposed between the first contact electrode and the second contact electrode.
delete The method according to claim 1,
The light emitting structure includes a region in which the first conductivity-type semiconductor layer is partially exposed,
The first contact electrode is a light emitting device positioned in a region where the first conductivity-type semiconductor layer is partially exposed.
The method according to claim 1,
The light emitting structure includes a plurality of holes partially exposing the first conductivity type semiconductor layer,
The first contact electrode is a light emitting device electrically connected to the first conductivity-type semiconductor layer through the plurality of holes.
The method according to claim 1,
Further comprising a first pad electrode and a second pad electrode positioned on each of the first bulk electrode and the second bulk electrode,
The insulating support covers a portion of upper surfaces of the first and second bulk electrodes, and the insulating support covers side surfaces of the first and second pad electrodes.
13. The method of claim 12,
The light emitting device wherein the first pad electrode is not located on the protrusion.
13. The method of claim 12,
A light emitting device having the same surface area as the first pad electrode and the second pad electrode.
The method according to claim 1,
The light emitting device further comprising a wavelength conversion unit positioned on the lower surface of the light emitting structure.
The method according to claim 1,
A distance between the first bulk electrode and the second bulk electrode is constant.
The method according to claim 1,
A horizontal cross-sectional area of the first bulk electrode is greater than a horizontal cross-sectional area of the second bulk electrode.
The method according to claim 1,
The protrusion of the first bulk electrode includes a first protrusion and a second protrusion protruding from the first protrusion,
The concave portion of the second bulk electrode includes a first concave portion and a second concave portion further recessed from the first concave portion.
19. The method of claim 18,
The second protrusion is a light emitting device positioned at a position overlapping the central portion of the light emitting device in a vertical direction.
19. The method of claim 18,
The second protrusion is formed of at least a portion of a polygonal, circular, or elliptical shape having an inscribed circle having a diameter of 50 μm or more, with the center of the light emitting device as the origin.
a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer;
first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively;
a connection electrode positioned on the second contact electrode;
an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes;
first and second bulk electrodes disposed on the light emitting structure and the insulating layer and electrically connected to the first and second contact electrodes, respectively; and
an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes;
the insulating layer includes a first opening and a second opening exposing the first contact electrode and the connection electrode, respectively;
An imaginary line extending along a separation region of a portion where the first bulk electrode and the second bulk electrode face each other has at least one bent portion,
A horizontal cross-sectional area of the first bulk electrode is greater than a horizontal cross-sectional area of the second bulk electrode.
22. The method of claim 21,
The starting point and the ending point of the virtual line are light emitting devices located on the same line.
a light emitting structure including a first conductivity type semiconductor layer, a second conductivity type semiconductor layer, and an active layer positioned between the first conductivity type semiconductor layer and the second conductivity type semiconductor layer;
first and second contact electrodes positioned on the light emitting structure and in ohmic contact with the first and second conductivity-type semiconductor layers, respectively;
a connection electrode positioned on the second contact electrode;
an insulating layer insulating the first and second contact electrodes and partially covering the first and second contact electrodes;
first and second bulk electrodes disposed on the insulating layer and electrically connected to the first and second contact electrodes, respectively; and
an insulating support covering side surfaces of the first and second bulk electrodes and at least partially exposing upper surfaces of the first and second bulk electrodes;
the insulating layer includes first and second openings exposing the first contact electrode and the connection electrode, respectively;
The first bulk electrode includes a first protrusion protruding from a side surface of the first and second bulk electrodes facing each other, and a second protrusion protruding from the first protrusion,
the second bulk electrode includes a first concave portion recessed from a side surface in which the first and second bulk electrodes face each other, and a second concave portion further recessed from the first concave portion;
The second protrusion is a light emitting device formed of at least a portion of a polygonal, circular, or elliptical shape having an inscribed circle having the center of the light emitting device as an origin.

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