Light emitting diode

A light emitting diode (LED) of a double hetero-junction type has a light-emitting layer of a GaAlInP material, a p-type cladding layer and an n-type cladding layer sandwiching the light-emitting layer therebetween, a p-side electrode formed on the p-type cladding layer side, and an n-side electrode formed on the n-type cladding layer side. The p-type cladding layer consists of a first p-type cladding layer positioned closer to the light-emitting layer and having a lower aluminum content and a lower impurity concentration, and a second p-type cladding layer positioned less closer to the light-emitting layer and having a higher aluminum content and a higher impurity concentration. The LED also has a current blocking layer below the p-side electrode for locally blocking electric current flowing from the p-side electrode to the n-side electrode.

BACKGROUND OF THE INVENTION

The present invention relates to a light emitting diode (LED) having a double hetero-structure and more particularly to an LED that has a high optical power and can be used at a large current.

The n-type GaAs buffer layer2is intended to eliminate defects of the n-type GaAs substrate1and influence of contaminants in the substrate and is not required if the n-type GaAs substrate1is surface-treated favorably. The p-type GaAs contact layer9has a Gads structure not containing Al to facilitate an ohmic contact between the p-type GaAs contact layer9and the p-side electrode11. The GaAs composing the contact layer9does not transmit light generated from the p-type (Ga0.7Al0.3)0.5In0.5P light-emitting layer4, but no problem is raised because the contact layer is formed immediately below the p-side electrode11.

An n-side electrode30is formed on the underside of the n-type GaAs substrate21. A p-side electrode31is formed on the p-type GaAs contact layer29.

A p-type cladding layer25is formed as a two-layer structure consisting of the p-type (Ga0.5Al0.5)0.5In0.5P first cladding layer26and the p-type Al0.5In0.5P second cladding layer27. Accordingly, it is possible to prevent a p-type impurity from diffusing to the p-type (Ga0.7Al0.3)0.5In0.5P light-emitting layer24although the p-type impurity has a large impurity gradient and is liable to diffuse when electric current flows through the LED for a long time. Thus it is possible to prevent deterioration of the optical power of the LED.

The LED is used in the form of a chip. Conventionally, an LED wafer is divided into chips of a size of 200 μm-300 μm by 200 μm-300 μm. In the above LEDs, the p-type GaAs contact layers9,29and the p-side electrodes11,31are formed circular and disposed at the center of each chip.FIG. 23shows a planar configuration of the chip.

The above LEDs have the following problem: Electric current flows immediately below the p-side electrodes11,31. Both the p-side electrodes11,31and the p-type GaAs contact layers9,29disposed under the p-side electrodes11,31are opaque. Thus, the p-side electrodes11,31and the contact layers9,29intercept light coming from parts of the p-type (Ga0.7Al0.3)0.5In0.5P light-emitting layers coming from parts of the p-type (Ga0.7Al0.3)0.5P light-emitting layers4,24that are located immediately below the p-side electrodes11,31. Thus, the light coming from those parts cannot be taken out to the outside. Accordingly, the above LEDs have a low light-emitting efficiency.

The LED chips are conventionally used at electric current LED having an intensity of several milliamperes to 50 mA. If the LED chip is used for an electric current having intensity higher than that, the optical power of the LED chip will saturate and characteristics will deteriorate with the passage of a current.

SUMMARY OF THE INVENTION

Therefore, it is an object of the present invention to provide an LED in which light emission immediately below an electrode is restricted to improve light take-out efficiency so that the LED has an improved light-emitting characteristic when it is used at a large current of several milliamperes to 50 mA or more.

In order to accomplish the above object, there is provided, according to an aspect of the invention, a light emitting diode of a double hetero-junction type comprising:

a light-emitting layer composed of a GaAlInP material;

a p-type cladding layer and an n-type cladding layer sandwiching the light-emitting layer therebetween;

a p-side electrode formed on the p-type cladding layer side; and

an n-side electrode formed on the n-type cladding layer side;

the p-type cladding layer consisting of a first p-type cladding layer positioned closer to the light-emitting layer and having a lower aluminum content and a lower impurity concentration, and a second p-type cladding layer positioned farther from the light-emitting layer and having a higher aluminum content and a higher impurity concentration; and

a current blocking layer for locally blocking electric current flowing from the p-side electrode to the n-side electrode.

The current blocking layer may be provided immediately below the p-side electrode which is opaque. With this arrangement, electric current flowing to those parts of the light-emitting layer that are positioned immediately below the p-side electrode is restricted. By thus suppressing emission of unrequired light which would be intercepted by the opaque p-side electrode, it is possible to enhance the light take-out efficiency and thus improve the optical power. That is, the external light emission efficiency can be enhanced.

If the thickness of the first p-type cladding layer is within a range of 0.2 μm to 0.5 μm inclusive, an initial luminous intensity ratio of 100% can be obtained. Thus, it is possible to increase reliability of the LED.

In one embodiment, the p-side electrode has an electrode window consisting of an opening, and the current blocking layer has an opening at a position confronting the electrode window of the p-side electrode, and the opening of the current blocking layer serves as a current path for intensively passing electric current from the p-side electrode through the light emitting diode.

According to the structure, the current density is increased and thus the internal light-emitting efficiency is also increased. There is a fear that the increase of the current density will reduce the optical power if electric current is passed through the LED for a long time. But such reduction of the optical power can be suppressed because the p-type cladding layer consists of the first and second layers.

An appropriate current density can be obtained by setting the area of the current path to the range of 1,000 μm2to 40,000 μm2. Consequently, the internal light-emitting efficiency can be enhanced. In the case where the area of the current path is set to the range of 1,000 μm2to 20,000 μm2, a comparatively dark portion is prevented from taking place in the center of the current path even when the diameter of the current path is 150 μm or more. In the case where the area of the current path is set to the range of 1,000 μm2to 10,000 μm2, a high optical power can be obtained even when the LED is driven at 20 mA.

In one embodiment, the p-side electrode is formed at a central portion of a surface, and the current blocking layer is formed at a position confronting the p-side electrode such that electric current coming from the p-side electrode flows around of the current blocking layer.

The p-side electrode may be formed at a central part of a surface of a layer. In this case, the LED, which has a high optical power, is fabricated by using the same electrode-forming process as that conventionally used.

The current blocking layer may be formed inside a current diffusion layer. In this case, the current blocking layer is located in a position nearer to the light-emitting layer than when the current blocking layer is formed on the upper surface of the current diffusion layer. Accordingly, it is possible to prevent electric current whose path has been restricted by the current blocking layer from being unfavorably diffused before it reaches the light-emitting layer.

There is also provided, according to a second aspect of the present invention, a light emitting diode of a double hetero-junction type in which a light-emitting layer made of a GaAlInP material is interposed between a p-type cladding layer and an n-type cladding layer, wherein:

a p-side electrode is formed on a p-type cladding layer-side surface having an area of 0.15 mm2or more; and

any point present in a region not containing the p-side electrode of the p-type cladding layer-side surface is within a distance of (Ld×2) from some point on an edge of the p-side electrode, where Ld is a distance from a position at which an optical power is maximum, to a position at which the optical power attenuates by 90%.

According to the construction, it is possible to obtain a favorable current diffusion and thus, suppress the increase of the current density. Therefore, even if the LED is used at a large electric current, the current density will not become too high. Accordingly, it is possible to prevent saturation of the optical power of the LED and deterioration in application of electric current to the LED. Thus, it is possible to improve the light-emitting characteristic at a large current.

When the distribution of the optical output of an LED chip is examined along a line A-A′, as shown inFIG. 17A, passing through a p-side electrode161, the distance Ld is a distance from a position close to the p-side electrode161at which the optical power is maximum, to a position at which the optical power attenuates by 90% as compared with the maximum value, as shown in FIG.17B. Then, according to the present invention, as shown in an explanatory illustration ofFIG. 18, the p-side electrode (denoted by162inFIG. 18) is provided such that any point present in a region not containing the p-side electrode of the p-type cladding layer-side surface is within the distance of (Ld×2) from the edge of the p-side electrode.

The p-side electrode may comprise a plurality of branch electrodes and a connection electrode connecting the branch electrodes to each other electrically.

In one embodiment, an interval between the branch electrodes is approximately Ld.

The surface on which the p-side electrode is formed may have two opposed parallel straight sides, and the branch electrodes may be each strip-shaped, and arranged parallel with the two sides and with each other.

In one embodiment, an interval between an outermost branch electrode and the side of the surface opposed to this branch electrode is approximately Ld/2.

Furthermore, according to a third aspect of the invention, there is provided a light emitting diode of a double hetero-junction type in which a light-emitting layer made of a GaAlInP material is interposed between a p-type cladding layer and an n-type cladding layer, comprising:

a current blocking layer formed on a p-type cladding layer-side surface having an area of 0.15 mm2or more; and

a p-side electrode formed at a position above the current blocking layer and opposed to the current blocking layer,

wherein any point present in a region not containing the current blocking layer of the p-type cladding layer-side surface is within a distance of (Ld×2) from some point on an edge of the current blocking layer, where Id is a distance from a position at which an optical power is maximum, to a position at which the optical power attenuates by 90%.

According to the construction, it is possible to obtain a favorable current diffusion and thus, suppress the increase of the current density. Therefore, even if the LED is used at a large electric current, the current density will not become too high. Accordingly, it is possible to prevent saturation of the optical power of the LED and deterioration in application of electric current to the LED. Thus, it is possible to improve the light-emitting characteristic at a large current.

Regarding the distance Ld, when the distribution of the optical output of an LED chip is examined along a line B-B′ passing through a p-side electrode163, as shown inFIG. 19A, the distance Ld is a distance from a position close to a current blocking layer164at which an optical power is maximum, to a position at which the optical power attenuates by 90% as compared with the maximum optical power, as shown in FIG.19B. Then, according to the present invention, as shown in an explanatory illustration ofFIG. 20, the current blocking layer (denoted by165inFIG. 20) is provided such that any point present in a region not containing the current blocking layer of the p-type cladding layer-side surface is within the distance of (Ld×2) from the edge of the current blocking layer.

In one embodiment, the current blocking layer comprises a plurality of blocking branch portions and a connection portion connecting the blocking branch portions to each other electrically, and an interval between adjacent blocking branch portions is approximately Ld.

The surface on which the current blocking layer may formed has two opposed parallel straight sides, and the blocking branch portions may be each strip-shaped and arranged parallel with the two sides and with each other.

In one embodiment, an interval between an outermost blocking branch portion and the side of the surface opposed to this outermost blocking branch portion is approximately Ld/2.

There is also provided, according to a fourth aspect of the present invention, a light emitting diode of a double heterojunction type in which a light-emitting layer made of a GaAlInP material is interposed between a p-type cladding layer and an n-type cladding layer, wherein:

a p-side electrode is formed on a p-type cladding layer-side surface, the p-side electrode consisting of a plurality of mutually connected constituent parts; and

any point present in a region not containing the p-side electrode of the p-type cladding layer-side surface is within a distance of (Ld×2) from some point on an edge of the p-side electrode, where Ld is a distance from a position at which an optical power is maximum, to a position at which the optical power attenuates by 90%.

In the LED according to any one of the second through the fourth aspects, if a current diffusion layer made of an AlGaInP material is provided between the p-type cladding layer and the p-side electrode, electric current favorably diffused by the p-side electrode or the current blocking layer is further diffused positively by the current diffusion layer. In this manner, it is possible to obtain more favorable current diffusion.

Also, if a barrier layer having a band gap intermediate between band gaps of the light-emitting layer and the p-type cladding layer is provided between the light-emitting layer and the p-type cladding layer, it is possible to prevent a p-type impurity from diffusing to the light-emitting layer, although the p-type impurity has a large impurity gradient and is liable to diffuse when electric current is passed through the LED for a long time. Thus it is possible to prevent deterioration of the optical output of the LED and improve the reliability thereof.

Furthermore, if a barrier layer having a band gap intermediate between band gaps of the light-emitting layer and the n-type cladding layer is provided between the light-emitting layer and the n-type cladding layer, it is possible to prevent an n-type impurity from diffusing to the light-emitting layer. Thus it is possible to prevent deterioration of the optical output power of the LED and improve the reliability thereof.

Other objects, features and advantages of the present invention will be obvious from the following description.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

An n-side electrode52is formed on the underside of the n-type GaAs substrate41. A p-side electrode53is formed on the p-type GaAs contact layer51.

In the LED having the structure is fabricated in the following manner. After the n-type GaAs buffer layer42through the n-type Ga0.9In0.1P current blocking layer49are sequentially formed on the n-type GaAs substrate41, the n-type Ga0.9In0.1P current blocking layer49is partly removed to form a current blocking structure. Then, the p-type Ga0.9In0.1P second current diffusion layer50is laminated on the n-type Ga0.9In0.1P current blocking layer49.

In the first embodiment, MOCVD (metal organic chemical vapor deposition) method is used for the film formation. But in the present invention, the film growth method is not limited to the MOCVD. For example, MBE (molecular beam epitaxy) method or MCMBE (metal organic molecular beam epitaxy) method may be used.

FIG. 2shows the LED, as viewed from above, in which the layers have been formed up to the current blocking structure. To collectively pass electric current through an internal portion of the LED, the current blocking structure of the first embodiment is constructed by providing the n-type Ga0.9In0.1P current blocking layer49so as to define a circular hole (current path)54therein. As in the case of the current blocking layer49, the p-side electrode53is also constructed so as to define a circular hole (electrode window)55therein to take out light emitted from the light-emitting layer44from the current path54inside the current blocking layer49and the electrode window55inside the p-side electrode53. In this case, the current density can be changed by varying the size of the current path54to thereby improve the light-emitting efficiency.

FIG. 3shows dependency of the optical power of the LED on a current density for different wavelengths of emitted light (namely, for colors of emitted light).FIG. 3indicates that the optical power is improved by increasing the current density. In particular, because the optical power of a short wavelength (green) depends on the current density, it is effective to use the current blocking structure formed of the current blocking layer49.

As described above, in the first embodiment, the following layers are sequentially formed on the n-type GaAs substrate41: the n-type GaAs buffer layer42, the n-type GaAlInP cladding layer43, the p-type GaAlInP light-emitting layer44, the p-type GaAlInP first cladding layer46, the p-type GaAlInP second cladding layer47, the p-type GaAlInP first current diffusion layer48, and the n-type GaInP current blocking layer49. Then, to form the current blocking structure, an internal portion of the current blocking layer49is removed circularly to form the current path54. Thereafter, the p-type GaInP second current diffusion layer50, the p-type GaAs contact layer51, and the p-side electrode53are sequentially formed on the current blocking layer49. Then, the electrode window55is formed by circularly removing a part disposed immediately above the current path54from the contact layer51and the p-side electrode53.

Accordingly, electric current discharged from the p-side electrode53formed in the periphery of the upper surface of the LED passes through the current path54inside the current blocking layer49and is collectively supplied into the light-emitting layer44. By constructing the LED such that electric current is prevented from flowing immediately below the opaque p-side electrode53, the light take-out efficiency can be improved. That is, according to the first embodiment, an LED having a high optical power can be provided.

FIG. 4shows the optical power of the LED having the current blocking structure formed of the current blocking layer49in comparison with that of the conventional LED not having the current blocking structure for different wavelengths of emitted light (for colors of emitted light).FIG. 4indicates that by providing the LED with the current blocking structure as carried out in the first embodiment, the optical power of the LED having the current blocking structure is improved 1.1-1.3 times as large as that of the conventional LED not having the current blocking structure.

In the second embodiment, the thickness of the first p-type cladding layer is larger than that of the first p-type cladding layer of the first embodiment to allow the LED of the second embodiment to have higher reliability than that of the first embodiment.FIG. 5is a vertical section view showing the layered structure of the LED of the second embodiment. The structure of each layer is as follows:Substrate141:made of n-type GaAsBuffer layer142:made of n-type GaAsN-type cladding layer143:made of n-type (Ga0.3Al0.7)0.5In0.5Pimpurity: Si, impurity concentration: 1×1018cm−3, andthickness: 1 μmLight-emitting layer144:made of p-type (Ga0.7Al0.3)0.5In0.5Pthickness: 0.5 μmFirst p-type cladding layer146:made of a p-type (Ga0.5Al0.5)0.5In0.5Pimpurity: Zn, impurity concentration: 1×1017cm−3, andthickness: 0.4 μmSecond p-type cladding layer147:made of p-type Al0.5In0.5Pimpurity: Zn, impurity concentration: 5×1017cm−3, andthickness: 1.0 μmFirst p-type current diffusion layer148:made of p-type GaPthickness: 1.0 μmN-type current blocking layer149:made of n-type GaPthickness: 0.5 μmSecond p-type current diffusion layer150:made of p-type Al0.01Ga0.98In0.01Pthickness: 7 μmContact layer151:made of p-type GaAs

An n-side electrode152is formed on the underside of the n-type GaAs substrate141. A p-side electrode153is formed on the p-type GaAs contact layer151.

The film thickness of the first p-type cladding layer146of the LED having the structure is 0.4 μm, while the film thickness of the first p-type cladding layer46of the first embodiment is 0.2 μm. By making the first p-type cladding layer146thicker than the first p-type cladding layer46, it is possible to improve the reliability of the LED and use the LED at a higher current density.FIG. 6shows the relationship between the film thickness of the first p-type cladding layer146of the LED and the deterioration of the optical characteristics of the LED when the diameter of the circular current path154is 70 μm and when electric current is passed through the LED for 1,000 hours at 50 mA. As obvious fromFIG. 6, it is preferable that the thickness of the first p-type cladding layer146is in the range of 0.2 μm to 0.5 μm. Further, an etching operation for forming the current path can be easily controlled by composing the first p-type current diffusion layer148and the n-type current blocking layer149of the GaP.

In the first t, the current path54is formed inside of the current blocking layer49. But the present invention is not limited to the mode of the first embodiment.

FIG. 7is a vertical sectional view showing an AlGaInP LED having a current path around a current blocking layer69. In the LED, as in the case of the LED shown inFIG. 1, the following layers are sequentially formed on an n-type GaAs substrate61: an n-type GaAs buffer layer62, an n-type (Ga0.3Al0.7)0.5In0.5P cladding layer63, a p-type (Ga0.7Al0.3)0.5In0.5P light-emitting layer64, a p-type (Ga0.5Al0.5)0.5In0.5P first cladding layer66, a p-type Al0.5In0.5P second cladding layer67, a p-type Ga0.9In0.1P first current diffusion layer68, and an n-type Ga0.9In0.1P current blocking layer69.

The periphery of the current blocking layer69is removed with its central part left circularly to form a current blocking structure. Then, a p-type Ga0.9In0.1P second current diffusion layer70is formed to cover the current blocking layer69. A circular p-type GaAs contact layer71and a circular p-side electrode73are formed on the second current diffusion layer70at a part thereof immediately above the circular current blocking layer69. An n-side electrode72is formed on the underside of the n-type GaAs substrate61.

In this case, as shown inFIG. 8which is a view as seen from above, the p-type GaAs contact layer71and the p-side electrode73are formed in a circular shape at the center of the second current diffusion layer70, as in the case of the conventional LED. Accordingly, the third embodiment has an advantage that the conventional process of manufacturing the p-type contact layer and the p-side electrode is applicable to the formation of the circular p-type GaAs contact layer71and the circular p-side electrode73.

The present invention is not limited to the mode of the first through third embodiments, but can be embodied by changing the configuration of the current blocking layer (current blocking structure) and that of the p-side electrode.

An n-side electrode92is formed on the underside of the n-type GaAs substrate81. A p-side electrode93is formed on the p-type GaAs contact layer91.

In the fourth embodiment, a p-type cladding layer85is formed as a two-layer structure consisting of the first p-type cladding layer86and the second p-type cladding layer87. Accordingly, it is possible to prevent a p-type impurity from diffusing to the light-emitting layer84although the p-type impurity has a large impurity gradient and is liable to diffuse when electric current is passed through the LED for a long time. Thus it is possible to prevent deterioration of the optical power. That is, in the fourth embodiment, the first p-type cladding layer86constitutes a barrier layer.

The LED having the structure is formed in the following manner. The n-type GaAs buffer layer82through the n-type Al0.01Ga0.98In0.01P current blocking layer89are sequentially formed on the n-type GaAs substrate81, and then, the n-type Al0.01Ga0.98In0.01P current blocking layer89is partly removed to form the current blocking structure. Then, the p-type Al0.01Ga0.98IN0.01P second current diffusion layer90is formed on the n-type Al0.01Ga0.98In0.01P current blocking layer89. The p-side electrode93is formed mediately above the current blocking layer89such that the p-side electrode93has the almost same planar configuration as that of the current blocking layer89. The light take-out efficiency is improved by thus blocking supply of electric current to the light-emitting layer84disposed immediately below the p-side electrode93which does not transmit light.

FIGS. 10A and 10Bshows the LED, as viewed from above, in a state in which the n-type GaAs buffer layer82through the current blocking structure have been formed and in a state in which the n-type GaAs buffer layer82through the p-side electrode93have been formed, respectively.FIG. 10Ashows a planar configuration of the p-side electrode93.FIG. 10Bshows a planar configuration of the current blocking layer89. As shown inFIG. 10B, the current blocking layer89has a planar configuration in which short strips (blocking branch portions) each having a width of 60 μm are arranged at regular intervals of 80 μm and are connected at one end thereof to a short strip (a connection portion) having the width of 60 μm. As shown inFIG. 10A, the p-side electrode93has a planar configuration in which short strips each having a width of 30 μm are arranged at regular intervals of 110 μm and connected at one end thereof to a short strip having the width of 30 μm. An LED wafer thus grown/formed is used by dividing it into chips of 560 μm×560 μm (area: 0.3136 mm2).

FIGS. 11A and 11Bshow the relationship between the configuration characteristics of the current blocking layer89and the optical power of the LED chip. The chip size is 560 μm×560 μm. The number of the short strips is two-five.FIG. 11Ashows the relationship between the interval between adjacent parts (namely, adjacent short strips) of the current blocking layer89and the optical power of the LED chip when electric current of 100 mA is passed through the LED chip.FIG. 11Aindicates that when the interval between adjacent blocking short strips is 80 μm, the optical power of the LED chip is the highest. Examining the distribution of the light emission intensity on the LED chip reveals that the light emission intensity attenuates by 90% at a position spaced about 80 μm from a short strip. Current diffusion can be considered to correspond to the light emission intensity. Accordingly, the light-emitting efficiency of the LED chip becomes maxim when the interval between two adjacent short strips of the current blocking layer89is set to a value equivalent to a distance to the position at which the current intensity attenuates by 90%.

FIG. 11Bshows the relationship between the percentage of the area of the current blocking layer89to the sectional area of the LED chip and the optical power of the LED chip when electric current of 100 mA flows therethrough.FIG. 11Bindicates that it is desirable to set the area of the current blocking layer89to 30% or more of the sectional area of the LED chip.

As described above, the current blocking layer89of the fourth embodiment has the planar configuration in which short strips each having a predetermined width are arranged at regular intervals and they are connected to each other at one end thereof with another short strip. The intervals between the adjacent short strips are set to values equal to or shorter than the distance from one short strip to the position at which the current intensity attenuates by 90%. The p-side electrode93is shaped to have a planar configuration in which short strips each having a predetermined width shorter than that of the current blocking layer89strips are arranged at predetermined intervals and connected to each other at one end thereof with another short strip. The p-side electrode93is formed immediately above the current blocking layer89.

When the LED is used at a large current, the current density will become too high. Consequently, the optical power of the LED chip will saturate and its performance and characteristics will deteriorate due to passage of electrical current. But according to the fourth embodiment, the attenuation rate of the intensity of electric current flowing the second p-type current diffusion layer90is set at 90% or more. Thus, it is possible to obtain a favorable current diffusion. That is, the LED of the fourth embodiment is constructed such that the current density is prevented from becoming too high in using electric current of about 100 mA, which is much greater than several milliamperes to 50 mA which has been used hithereto. Thus, it is possible to improve the light-emitting characteristic of the LED.

The distance at which the light emission strength attenuates by 90% changes according to the thickness and dope density of the second p-type current diffusion layer90. Therefore, it is necessary to optimally set the interval between the adjacent short strips of the current blocking layer89, according to the changeable distance at which the light emission intensity attenuates by 90%.

An n-side electrode110is formed on the underside of the n-type GaAs substrate101. A p-side electrode111is formed on the p-type GaAs contact layer109. An LED wafer thus grown/formed is used by dividing it into chips of 560 μm×560 μm.

FIG. 13shows the LED as viewed from above. The p-side electrode111has a planar configuration in which short strips each having a width of 60 μm are arranged at regular intervals of 80 μm and connected to each other at one end thereof with another short strip having the width of 60 μm. Although the LED of the fifth embodiment does not have the current blocking layer unlike the third embodiment, the interval between adjacent branch electrodes (short strips) of the p-side electrode111is set to a value equal to or shorter than the distance at which the current intensity attenuates by 90%. In this case as well, it is possible to improve the light-emitting characteristic of the LED when it is used at a large current of about 100 mA.

FIG. 14is a vertical sectional view showing an AlGaInP LED having improved light-emitting characteristic when it is used at a large current owing to its construction different from that of the fourth and fifth embodiments. In the LED, as in the case of the LED ofFIG. 9, the following layers are sequentially provided on the n-type GaAs substrate121: an n-type GaAs buffer layer122, an n-type (Ga0.3Al0.7)0.5In0.5P cladding layer123, a p-type (Ga0.7Al0.3)0.5In0.5P light-emitting layer124, a p-type (Ga0.5Al0.5)0.5In0.5P first cladding layer126, a p-type Al0.5In0.5P second cladding layer127, a p-type Al0.01Ga0.98In0.01P first current diffusion layer128, and an n-type Al0.01Ga0.98In0.01P current blocking layer129.

Then, the n-type current blocking layer129is partly removed to form a current blocking structure. Then, a p-type Al0.01Ga0.98In0.01P second current diffusion layer130is formed on the n-type current blocking layer129. A p-type GaAs contact layer131and a p-side electrode133, which has a shape analogous to the current blocking layer129, are formed on the second current diffusion layer130at a part positioned immediately above the current blocking layer129. An n-side electrode132is formed on the underside of the n-type GaAs substrate121.

FIGS. 15A and 15Bshow the LED, as viewed from above, in a state in which the n-type GaAs buffer layer122through the current blocking structure have been formed, and in a state in which the n-type GaAs buffer layer122through the p-side electrode133are formed, respectively.FIG. 15Ashows a planar configuration of the p-side electrode133.FIG. 15Bshows a planar configuration of the current blocking layer129. As shown inFIG. 15A, the p-side electrode133has a planar configuration in which a plurality of concentric circular electrodes are connected to each other with a connection electrode. As shown inFIG. 15B, the current blocking layer129has a planar configuration in which a plurality of concentric circular blocking parts are connected to each other with a connection. The width of each circular electrode of the p-side electrode133is 30 μm. The interval between the adjacent circular electrodes of the p-side electrode133is 110 μm. The width of each circular blocking part of the current blocking layer129is 60 μm. The interval between the adjacent circular blocking parts is 80 μm. Under these conditions, the optical power of the LED of the sixth embodiment is almost the same as that of the LED of the fourth embodiment. That is, when the LED is used at a large current, the effect of improving the light-emitting characteristic, which is brought about by the improvement of the p-side electrode and the current blocking layer, is determined not by the shapes of the p-side electrode and the current blocking layer, but by the widths of the electrode and the blocking layer and the intervals between the parts of the electrode and between the parts of the current blocking layer.

Accordingly, the planar shape of the p-side electrode and that of the current blocking layer of the present invention are not limited to those shown inFIGS. 10,13, and15. A high light-emitting efficiency is also obtainable even by adopting shapes shown inFIGS. 16A-16C.

Needless to say, the size of the LED chip of the present invention is not limited to 560 μm×560 μm. In each embodiment, the n-type cladding layer is formed as a single layer, but may be formed as a two-layer structure consisting of first and second n-type cladding layers. In this case, an n-type cladding layer closer to the light-emitting layer may be used as the barrier layer to prevent the diffusion of the n-type impurity to the light-emitting layer. Thereby, it is possible to obtain an LED having higher reliability.