DE10044500A1 - More reliable blue LED requiring only single wire bonding, is formed by GaN-based layers on substrate surrounded by e.g. cup-shaped conductor frame - Google Patents

Abstract

The first GaN-based semiconductor layer (402) is formed on the insulating substrate (401), and is higher in the center. An intermediate GaN-based active layer (404) on the central section emits light. A second GaN-based layer (406) above this, lies below the first electrode (409). A conducting layer (411) covers the sidewalls and underside of the insulating substrate and is in electrical contact with the sidewalls of the first semiconductor layer. An Independent claim is included for the method of manufacture, essentially by a sequence of layer formation and selective etching.

Description

The invention relates to a compound semiconductor component and a method of manufacturing the same. More accurate said, the invention relates to such a component, specifically a light emitting diode (LED) based on GaN, the side walls and bottom with a conductive Coating are covered, as well as a method for Manufacture of the same.  

Compound semiconductors have opened in recent years GaN base always use more attention than Material for making blue, green, or teal Light-emitting components, such as blue LEDs or blue laser diodes (LDs). A blue LED indicates z. B. generally a structure with at least one GaN-based n-type compound semiconductor layer, an active one Layer of an intrinsically conductive or doped Compound semiconductor material based on GaN and at least a p-compound semiconductor layer based on GaN, which are sequentially laminated to a substrate.

When producing a conventional blue LED in the Generally as a material for the substrate thereof transparent sapphire used. Deviating from one Semiconductor substrate as it is for other light-emitting Components used, sapphire is an electrical insulating material. Accordingly, it is impossible to to form an n-electrode directly on this substrate. As a solution to this problem, an n- GaN-based compound semiconductor layer by etching the blue LED partially exposed to a conductive To create area on which an n-electrode is effective can be manufactured.

Reference is now made to the accompanying FIG. 1 in order to make the conventional blue LED outlined above easier to understand. This LED essentially has a sapphire substrate 101, an n-type compound semiconductor layer 102 based on GaN, an active layer 103 made of an intrinsically conductive or doped compound semiconductor material based on GaN and a p-type compound semiconductor layer 104 based on GaN. As indicated above, an n-electrode 105 is formed on the exposed surface of the n-type GaN-based semiconductor layer 102 , while a p-electrode 106 is made on the p-type GaN-based semiconductor layer 104 .

However, the conventional blue LED shown in Fig. 1 has various disadvantages, as indicated below. First, the insulating sapphire substrate 101 of this blue LED does not make an electrical connection to a cup-shaped lead frame 107 when it is mounted on the surface thereof. In order to electrically connect the blue LED to the cup-shaped lead frame 107 , it is necessary to use a metal bond wire 108 to connect the n-electrode 105 to the surface of the cup-shaped lead frame 107 , as shown in FIG. 2. Since the p-electrode 106 is to be electrically connected to a separate lead frame 110 with another metal bonding wire 109 , the wire bonding process has to be carried out twice in order to ensure that the conventional blue LED is completely connected. In addition, the metal bond wire 109 is preferably connected to the p-electrode 106 by means of a bond pad 111 . As a result of these two wire bonding processes, the manufacturing process for a conventional blue LED is complicated, and the chip size of such an LED is large, which leads to high manufacturing costs.

In addition, the structure and arrangement of the electrodes 105 , 106 in the conventional blue LED are asymmetrical as shown in FIG. 3, which is a plan view of the blue LED shown in FIG. 1. As a result, the electric current inside the conventional blue LED does not flow symmetrically in the top-down direction. Therefore, it is very difficult for the conventional blue LED to achieve a uniform power distribution characteristic. Since the current distribution characteristic is uneven, there are several points with a high current density in a conventional blue LED, at which damage can easily occur during operation.

Furthermore, the well-known problem of electrostatic discharge (ESD) occurs in the insulating sapphire substrate 101 inevitably.

The disadvantages mentioned above worsen the functionality and reliability of a conventional blue LED in a significant way.

Accordingly, it is desirable to create a blue LED in which a single wire bonding step is possible, so that the manufacturing process is not complicated and the Manufacturing costs can not be increased. It is also desirable to create a blue LED that one shows uniform power distribution characteristics and free of mentioned ESD problem is. It is also desirable to create a blue LED that is on its bottom  a mirror-shaped reflector is provided to thereby to improve the light emission efficiency of this LED.

The invention has for its object a light to create an emissive compound semiconductor component, a single wire bonding step in its manufacture is required to simplify the manufacturing process and reduce manufacturing costs.

Another object of the invention is to provide a Compound semiconductor component with uniform To create power distribution characteristics.

Yet another object of the invention is a Light-emitting compound semiconductor component create that free from the problem of electrostatic discharge (ESD) is.

Yet another object of the invention is a Light-emitting compound semiconductor component with a mirror-shaped formed on its underside Creating reflector.

Another object of the invention is a method for producing such a compound semiconductor Component.

The light emitting according to the invention Compound semiconductor device is in appended claim 1 specified during the manufacturing process according to the invention for such a component is specified in claim 11.  

Advantageous refinements and developments are Subject of respective dependent claims.

On the side walls and the bottom of the insulating Substrate is preferably an adhesive layer, on which the conductive coating layer is then produced. The adhesive layer is used to improve the adhesive properties between the first electrode and the conductive layer improve.

The conductive layer is preferably one translucent layer.

These and other tasks, features and benefits of Invention will be made with reference to the following Description and the accompanying drawings better seen.

Fig. 1 is a sectional view of a conventional blue LED;

Fig. 2 is a sectional view of the LED of Fig. 1 when mounted on a cup-shaped lead frame;

Fig. 3 is a plan view of the LED of Fig. 1, showing the arrangement of the electrodes thereof;

FIG. 4 (a) to 4 (e) are sectional views showing steps of fabricating a blue LED according to a first embodiment of the invention;

Fig. 5 is a plan view showing the arrangement of the electrodes of the blue LED of Fig. 4 (e);

Fig. 6 is a sectional view showing the blue LED of Fig. 4 (e) mounted on a cup-shaped lead frame;

Fig. 7 (a) to 7 (c) are sectional views showing steps of fabricating a blue LED according to a second embodiment of the invention;

Fig. 8 is a sectional view showing the blue LED of Fig. 7 (c) in a state mounted on a cup-shaped lead frame; and

FIGS. 9 and Fig. 10 are sectional views of a blue LED and a fourth embodiment of the invention, which are each mounted on a cup-shaped lead frame according to a third.

Now the preferred embodiments of the Invention with reference to the drawings in Described individually.

First embodiment

Steps for producing a blue LED 400 according to a first exemplary embodiment of the invention will now be explained with reference to FIGS. 4 (a) to 4 (e).

According to Fig. 4 (a), an n-layer 402 is formed on an insulating substrate 401 microns with a thickness of 3 to 5, which is generally made of sapphire. On this n-layer 402 , an n-confinement layer 403 with a thickness of 0.1 to 0.3 μm, an active layer 404 with a thickness of 50 to 200 nm (500 to 2000 Å) for emitting light, a p Conclusion layer 405 with a thickness of 0.1 to 0.3 μm and a p-layer 406 with a thickness of 0.2 to 1 μm are produced sequentially from a compound semiconductor material based on GaN. For example, a quaternary compound semiconductor material in the form of In _x Al _y Ga _1-xy N with different conductivity types and concentrations of dopants can be used to produce the layers 402 to 406 , the mole fractions x, y being the conditions 0 ≦ x <1, 0 ≦ y <1 and x + y <1 are sufficient. It should be pointed out that the structure of the blue LED 400 according to the invention can be any, that is to say that in practice the structure is not restricted to that described in this first exemplary embodiment.

According to Fig. 4 (b), the blue LED 400 is etched by photolithography using a mask of a predetermined pattern in such a manner that the edge portion is removed. By precisely controlling the etching time, the etching depth is set with sufficient depth to expose the n-layer 402 . Preferably, the n-layer 402 is slightly etched, so that the exposed surface 402 a of the edge section of the n-layer 402 lies deeper than the surface 402 b of the central section of this layer, ie the interface between it and the n-confinement layer 403 . After the etching process is complete, the blue LED 400 remains as a mesa-shaped structure, in which the upper side walls 400 a are further inward than the lower side walls 400 b. In this embodiment, the preferred etching process is a dry etching process.

According to Fig. 4 (c) the p-layer, a p-electrode made 406,409 of any metal on the surface that can form an ohmic contact with the p-type p-compound semiconductor material based on GaN. For example, p-electrode 409 is made of Ni, Ti, Al, Au, or an alloy thereof. When producing the p-electrode 409 , a transparent contact layer (TCL = Transparent Contact Layer) 407 with a thickness of 5 to 25 nm is preferably inserted between the p-layer 406 and the p-electrode 409 in order to cover the entire surface of the p- Essentially cover layer 406 , thereby simultaneously increasing the light emission efficiency and the current distribution uniformity of the blue LED 400 . The TCL 407 is a translucent layer for ohmic contact made of a conductive material, Au, Ni, Pt, Al, Sn, In, Cr, Ti or an alloy thereof.

According to Fig. 4 (d) an elastic band is positioned 410 made of polyvinyl chloride (PVC) on the blue LED 400 and then to its upper side and the upper side walls 400 a thereof, and the exposed surface 402 to cover a of the n-layer 402. As a result, only the lower side walls 400 b and the underside 400 c of the blue LED 400 are exposed.

According to Fig. 4 (e), a conductive layer 411 is then applied immediately so that the lower side walls 400 b and the bottom surface 400 c of the blue LED 400 is covered to form an n-electrode. The upper side and the upper side walls 400 a of the blue LED 400 and the exposed surface 402 a of the n-layer 402 are protected against contact by the conductive layer 411 by the elastic band 410 . Any metal capable of forming an n-type ohmic contact with the n-layer 402 , for example Au, Al, Ti, Cr or an alloy thereof, can be used as the material for the conductive layer 411 , Then the elastic band 410 is removed to expose the top and the upper side walls 400 a of the blue LED 400 and the exposed surface 402 a of the n-layer 402 after the production of the conductive layer 411 . Since the conductive layer 411 electrically contacts the n-layer 402 on its side walls 402 b, it is effectively used as an n-electrode. The blue LED 400 of the first exemplary embodiment of the invention is thus obtained.

FIG. 5 is a plan view of the blue LED 400 of the first embodiment shown in FIG. 4 (e). As can be seen, both the structure and the arrangement of the p-electrode 406 and the conductive layer 411 , which serves as the n-electrode, are symmetrical. As a result, the electric current flows from the p-electrode 409 in the blue LED 400 from top to bottom to the conductive layer 411 and spreads outward in the radial direction as shown by arrows in FIG. 5. Therefore, the blue LED 400 of this embodiment can very effectively achieve a uniform power distribution characteristic. Therefore, there are no points of high current density in it, which greatly increases the reliability and the service life of this blue LED 400 . It should be noted that the shapes of the p-electrode 409 and the conductive layer 411 are not limited to the special shapes shown in FIG. 5, but that they can be of any shape.

FIG. 6 is a sectional view illustrating a way of bonding the blue LED 400 according to the first embodiment of the invention to a cup-shaped lead frame 107 and a separate lead frame 110 . Since the conductive layer 411 is electrically connected to the n-layer 402 and it covers the underside 400 c of the blue LED 400 , this n-layer 402 is electrically connected via the conductive layer 411 to the surface of the cup-shaped lead frame 107 when the blue LED 400 is mounted on this. In other words, it is not necessary to connect the n-layer 402 to the cup-shaped lead frame 107 using any bonding wires. As a result, only the electrical connection between the p-electrode 409 and the separate lead frame 110 requires a bonding wire 109 . Accordingly, the blue LED 400 according to this embodiment can be manufactured with a single wire bonding step, so that the manufacturing process is simplified and the manufacturing costs are reduced.

Furthermore, the conductive layer 411 covering the lower side walls 400 b and the underside 400 c of the blue LED 400 not only provides an ESD protection path, but also acts as a mirror-shaped reflector which reflects the light emitted by the active layer 404 , thereby to increase the light emission efficiency of the blue LED 400 .

Second embodiment

In Figs. 7 (a) to 7 (c), which serve to illustrate the preparation of a blue LED 700 according to the second embodiment of the invention, similar elements are numbered as in Figs. 4 (a) to 4 (e) shown blue LED 400 marked with similar reference numerals. For the sake of simplicity, only differences between the second and first exemplary embodiments are explained below.

According to FIG. 7 (a), after the semiconductor structure shown in FIG. 4 (b) has been produced, an n-electrode 708 without an electrical connection to the upper side walls 400 a is produced on the exposed surface 402 a of the n-layer 402 , while the p-electrode 409 is produced without electrical connection to the n-electrode 708 on the surface of the p-layer 406 . The n and p electrodes 708 and 409 can be made of any metal capable of making n and p type ohmic contact with the n and p compound GaN based semiconductor material, respectively , For example, both the n and p electrodes 708 and 409 in this embodiment are made of Ni, Ti, Al, Au, or an alloy thereof.

According to Fig. 7 (b) is then attached an elastic band 410 made of PVC on the blue LED 700 so that the top thereof covered. As a result, only the n-electrode 708 and the lower side walls 400 b and the underside 400 c of the blue LED 700 are exposed.

According to Fig. 7 (c), a conductive layer 411 is applied so then that they directly the n-electrode 708, the lower side walls 400 b and the bottom surface 400 c of the blue LED 700 is covered. The upper side of the blue LED 700 is protected by the elastic band 410 against contact by the conductive layer 411 . The material for the conductive layer 411 can e.g. B. Au, Al, Ti, Cr or an alloy thereof. The elastic band 410 is then removed to expose the top of the blue LED 700 after the formation of the conductive layer 411 . Thus, the blue LED 700 of the second embodiment of the invention is completed.

Fig. 8 is a sectional view for illustrating a manner of Aufbonden this blue LED 700 on a cup-shaped lead frame 107 and a separate lead-frame 110. Since the conductive layer 411 is electrically connected to the n-electrode 708 and it covers the underside 400 c of the blue LED 700 , the n-electrode 708 is electrically connected via the conductive layer 411 to the top of the cup-shaped lead frame 107 when the blue one LED 700 is mounted on this. In other words, it is not necessary to use any bonding wires to electrically connect the n-electrode 708 to the cup-shaped lead frame 107 . As a result, only the electrical connection between the p-electrode 409 and the separate lead frame 110 requires the use of a bonding wire 109 . Accordingly, the blue LED of this second embodiment requires only a single wire bonding step, which reduces the complexity of the manufacturing process and lowers the manufacturing cost.

Third embodiment

In the sectional view of FIG. 9 of a blue LED 900 according to a third exemplary embodiment of the invention, the elements thereof which are similar to those of the blue LED 700 shown in FIGS . 7 (a) to 7 (c) are identified with similar reference numbers. For the sake of simplicity, only the difference between the third exemplary embodiment and the second is explained below.

During the manufacture of this blue LED 900 , almost all of the fabrication steps are the same as those for the blue LED 700 shown in Figs. 7 (a) to 7 (c), except that an adhesive layer 901 is applied which is the n-electrode 708 , the lower side walls 400 b and the underside 400 c of the structure of the LED 900 covered and on which the conductive layer 411 is applied. The adhesive layer 901 is used to improve the adhesive properties between the side walls and the bottom of the insulating substrate 401 and the conductive layer 411 . The material of the adhesive layer 901 can be Ti, Ni, Al, Cr, Pd or any other metal that can improve the adhesive properties between the side walls and the underside of the insulating substrate 401 and the conductive layer 411 .

Fourth embodiment

In the sectional view of FIG. 10 of a blue LED 1000 according to a third exemplary embodiment of the invention, the elements thereof which are similar to those of the blue LED 700 shown in FIGS . 7 (a) to 7 (c) are identified with similar reference numbers. For the sake of simplicity, only the difference between the third exemplary embodiment and the second is explained below.

As described in the second exemplary embodiment, the light generated in the active layer 404 is emitted by the blue LED 700 through its upper side, ie the p-layer 406 . However, the fourth exemplary embodiment relates to a blue LED 1000 , which emits the light emitted in its active layer 404 through the underside, ie the insulating substrate 401 .

In order to obtain such a blue LED 1000 , the conductive layer 1001 is produced as a light-transmitting layer which transmits the light generated in the active layer 404 . An indium tin oxide (ITO) layer, a cadmium tin oxide (CTO) layer, a zinc oxide (ZnO) layer or a thin metal layer with a thickness in the range of 0.001 to 1 μm made of Au, Ni, Pt, can be used as the light-transmitting conductive layer 1001 . Al, Sn, In, Cr, Ti or an alloy thereof can be used.

Furthermore, p-electrode 1002 is made to cover substantially the entire surface of p-layer 406 . In the fourth embodiment, the p-electrode 1002 is used as a mirror-shaped reflector to reflect the light generated in the active layer 404 , thereby increasing the light emission efficiency of the blue LED 1000 .

When this blue LED 1000 of the fourth embodiment is mounted on the cup-shaped lead frame 107 , it is turned upside down to connect the p-electrode 1002 to the surface of the cup-shaped lead frame 107 as shown in FIG. 10. Next, the translucent conductive layer 1001 is electrically connected to the separate lead frame 106 by means of a bonding wire 109 . In order to improve the bond strength between the light-transmitting conductive layer 1001 and the bond wire 109 , a bond pad 1003 is preferably used.

Similar to the second exemplary embodiment, in the blue LED 1000 of the fourth exemplary embodiment, only a single bond wire 109 is required in spite of the different mounting orientation. Accordingly, even with the blue LED 1000, only one bonding step is required for a single wire, which simplifies the complexity of the process and lowers the manufacturing costs. Furthermore, the translucent conductive layer 1001 , which covers the side walls and the underside of the insulating substrate 401 of the blue LED 1000 , provides an ESD protection path.

Claims (21)

1. Translucent compound semiconductor component with:
an insulating substrate ( 401 );
a first GaN-based semiconductor layer ( 402 ) formed on the top of the insulating substrate and the surface of which in the central portion is higher than the surface of its peripheral portion;
an active layer ( 404 ) provided on the surface in the central portion of the first GaN-based semiconductor layer to generate light;
a second GaN-based semiconductor layer ( 406 ) provided on the active layer;
a first electrode ( 409 ) and present on this second GaN-based semiconductor layer
a conductive layer ( 411 ) covering the side walls and the bottom of the insulating substrate and in electrical contact with the side walls of the first GaN-based semiconductor layer. 2. Hauteil according to claim 1, characterized by:
a second electrode ( 708 ) made on the surface of the edge portion of the first GaN-based semiconductor layer ( 402 ) without the active layer ( 404 ), the second GaN-based semiconductor layer ( 406 ) and the first electrode ( 409 ) to be electrically connected;
wherein the conductive layer ( 411 ) is electrically connected to the second electrode. 3. The component according to claim 1, characterized in that the first GaN-based semiconductor layer ( 402 ) is doped for a first conductivity type, while the second GaN-based semiconductor layer ( 406 ) is doped for a second conductivity type. 4. Component according to claim 3, characterized in that the first conduction type is the n type and the second Line type is the p-type. 5. Component according to claim 3, characterized by:
a first confinement layer ( 403 ) made of a first conductivity type GaN-based semiconductor material which is present between the first GaN-based semiconductor layer ( 402 ) and the active layer ( 404 ); and
a second confinement layer ( 405 ) made of a second conductivity type GaN-based semiconductor material, which is present between the active layer and the second GaN-based semiconductor layer ( 406 ). 6. The component according to claim 1, characterized by an adhesive layer ( 901 ) between the side walls and the underside of the insulating substrate ( 401 ) and the conductive layer ( 411 ). 7. The component according to claim 1, characterized in that the conductive layer ( 411 ) is designed as a mirror-shaped reflector. 8. The component according to claim 1, characterized in that the conductive layer ( 411 ) is an indium tin oxide layer, a cadmium tin oxide layer or zinc oxide layer. 9. The component according to claim 1, characterized in that the conductive layer ( 411 ) is a thin metal layer with a thickness in the range of 0.001 to 1 µm made of Au, Ni, Pt, Al, Sn, In, Cr, Ti or an alloy thereof is. 10. The component according to claim 1, characterized in that the GaN-based semiconductor is a quaternary compound semiconductor of the type In _x Al _y Ga _1-xy N, the mole fractions x, y satisfying the following conditions: 0 ≦ x <1, 0 ≦ y <1 and x + y <1, 11. A method for producing a light-emitting compound semiconductor device, comprising the following steps:

• - producing an insulating substrate ( 401 );
• - producing a first semiconductor layer ( 402 ) based on GaN on this insulating substrate;
• - forming an active layer ( 404 ) above this first GaN-based semiconductor layer to generate light;
• - producing a second semiconductor layer ( 406 ) based on GaN above the active layer;
• Etching the edge portions of the second GaN-based semiconductor layer, the active layer and the first GaN-based semiconductor layer in such a way that the exposed surface in the edge portion of the first GaN-based semiconductor layer is lower than the surface of the central portion of this layer ;
• - Manufacturing a first electrode ( 409 ) on the second semiconductor layer based on GaN and
• - Applying a conductive layer ( 411 ) such that it covers the side walls and the underside of the insulating substrate and is electrically connected to the side walls of the first GaN-based semiconductor layer.

12. The method according to claim 11, characterized by the step of producing a second electrode ( 708 ) on the exposed surface in the edge portion of the first semiconductor layer ( 402 ) based on GaN without electrical connection to the active layer 404 , the second semiconductor layer ( 406 ) based on GaN and the first electrode ( 409 ). 13. The method according to claim 11, characterized in that the first GaN-based semiconductor layer ( 402 ) is doped for a first conductivity type and the second GaN-based semiconductor layer ( 406 ) is doped for a second conductivity type. 14. The method according to claim 13, characterized characterized in that the first line type is the n-type and the second conduction type is the p-type. 15. The method according to claim 13, characterized by the following steps:   - producing a first confinement layer ( 403 ) of. first conductivity type on the first GaN-based semiconductor layer ( 402 );

• Forming a second confinement layer ( 405 ) of the second conductivity type on the active layer ( 404 ) and
• Etching the edge portions of the first confinement layer and the second confinement layer.

16. The method according to claim 11, characterized by the step of producing an adhesive layer ( 901 ) on the side walls and the underside of the insulating substrate ( 401 ) before the step of applying the conductive layer ( 411 ). 17. The method according to claim 11, characterized in that the conductive layer ( 411 ) is produced as a mirror-shaped reflector. 18. The method according to claim 11, characterized in that the conductive layer ( 411 ) is made of indium oxide, cadmium tin oxide or zinc oxide. 19. The method according to claim 11, characterized in that the conductive layer ( 411 ) as a thin metal layer with a thickness in the range of 0.001 to 1 µm made of Au, Ni, Pt, Al, Sn, In, Cr, Ti or an alloy thereof will be produced. 20. The method according to claim 11, characterized in that the GaN-based semiconductor is a quaternary compound semiconductor of the type In _x Al _y Ga _1-xy N, the mole fractions x, y satisfying the following conditions: 0 ≦ x <1, 0 ≦ y <1 and x + y <1.