Very High Efficiency GaP Green Light Emitting Diodes

Lorimor, O. G.; Dapkus, P.D.; Hackett, W. H.

doi:10.1149/1.2134224

Cited by 19 publications

(6 citation statements)

References 16 publications

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“…The refinement of our LPE technique with O getters increased the diffusion lengths still further. This is consistent with the recent results of Lorimor et al (15) who report that deliberate addition of small amounts of oxygen to the inlet gas produced a pronounced reduction in the quantum efficiency and minority carrier lifetimes.…”

Section: Resultssupporting

confidence: 93%

“…However, associated complexes of oxygen such as Si-O (13), VG~-O (14), etc., may play a role in the recombination efficiency in both the n-and p-layers of an LED. Evidence to support this hypothesis has been reported by a number of workers (15)(16)(17)(18). It is therefore clear that in order to improve the EL and generate purer spectra in green LED's all traces of oxygen must be removed from both the n-and p-layers.…”

mentioning

confidence: 80%

“…Residual traces of oxygen in the Ga melt or oxygen present in the gas stream could be further reduced by using O getters such as Mg, A1, or St. Reactions between these getter elements and 02, H20, and Ga203 are also listed in Table I (reactions 9, 10, [14][15][16][18][19][20].…”

Section: Chemical Interactions Of Getters With Oxygen and Nitrogenmentioning

confidence: 99%

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Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Mürau

Bhargava

1976

J. Electrochem. Soc.

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Improvement in the minority carrier diffusion lengths has been obtained in GaP:N LED's by controlling the oxygen contamination during LPE with getter dopants such as Al, Mg, or Si. Experimental data are presented which show a limited range in which one can achieve oxygen gettering in GaP without reducing the incorporation of nitrogen. Excess A1 produces free exciton emission with an external quantum efficiency of 0.02% at 4 A/cm 2. ) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 128.255.6.125 Downloaded on 2015-03-17 to IP ) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 128.255.6.125 Downloaded on 2015-03-17 to IP ) unless CC License in place (see abstract). ecsdl.org/site/terms_use address. Redistribution subject to ECS terms of use (see 128.255.6.125 Downloaded on 2015-03-17 to IP

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Section: Resultssupporting

confidence: 93%

mentioning

confidence: 80%

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Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Mürau

Bhargava

1976

J. Electrochem. Soc.

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“…4, the etch-pit denSity in the substrate can range from (a) -5X 10 4 cm-2 near the center , to (c) ~7X105 cm-2 near the edge of a slice o Moreover, the localized dislocation distribution is often nonuniform o Dislocations tend to form a cellular substructure, with walls of high dislocation density surrounding nearly dislocation-free areas o This behavior is particularly conspicuous for regions (b) midway between the center and the edge; within the walls, the dislocation density can be ~ 1 x 10 6 cm-2 o (Note the Similarity to the dislocation configurations in Fig. 10 ) In addition, bands of very high dislocation density (locally up to ~ 3 X 10 6 cm-2 ) lying along (211) directions and originating at intervals around the slica periphery are observed (d); it is believed that these bands may serve as sites for fracture initiation which can occur during chemical polishingo 20 The ordered dislocation arrays (observed also by x-ray topography20) in the LEC GaP wafers represent lower energy configurations than random dislocations and are reminiscent of substructures in metals which have been extenSively discussed o 21 Formation of the ordered arrays requires dislocation climb and thus necessarily takes place at elevated temperatures where gallium and phosphorus vacancies and/or interstitials have appreciable concentrations and mobilities 0…”

Section: Dislocation Configurationsmentioning

confidence: 59%

Effect of dislocations on green electroluminescence efficiency in GaP grown by liquid phase epitaxy

Brantley¹,

Lorimor²,

Dapkus³

et al. 1975

Journal of Applied Physics

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The origins of dislocations in GaP grown by liquid phase epitaxy (LPE) and their effects upon green electroluminescence (EL) efficiency have been investigated by chemical etch pitting and scanning electron microscopy. Under normal growth conditions, the dislocation etch pit density (Pn) and configuration in the epitaxial layers are controlled by, and are approximately the same as, that in the liquid encapsulated Czochralski substrate. All dislocations which are revealed by chemical etching in the p LPE layer cause a localized reduction in luminescence. The dislocations are shown to behave as regions of rapid (nonradiative) recombination. Typically, reductions of a factor of -2 in green EL efficiency occur when Pn for the LPE layers is in the -2-5 X 10 5 cm-2 range, corresponding to an average separation of about two to four diffusion lengths in this material. The experimental results are supported by a simple theoretical model for the effects of dislocations on EL efficiency. These considerations explain why dislocations in GaP LPE layers for red light-emitting diodes (LED's), in contrast to green LED's, typically have no significant effect on EL efficiency since diffusion lengths are much shorter in the red LED's. PACS numbers: 78.60.F, 85.6O.J, 61.70.M [This article is copyrighted as indicated in the article. Reuse of AIP content is subject to the terms at: http://scitation.aip.org/termsconditions. Downloaded to ] IP: 128.82.252.58 On: Tue

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“…As already discussed in an earlier paper [7], the photoluminescence intensity is proportional to the minority-carrier lifetime, majority-carrier concentration and the nitrogen concentration in the considered doping range. The measured minority-carrier lifetime [8] of holes in the n-type crystal near the p-n junction is τ h = 110-250 ns, which is about 1.3-2 times of the minority-carrier lifetime of an electron in the p-type crystal (τ e = 85-185 ns). While the majority-carrier (Zn) concentration in the p-type region is about 10 times that of the majority carrier (S) in the n-type region, the photoluminescence intensity of the p-type region will be distinctively higher than that of the n-type region when there is a comparative nitrogen concentration doped on both sides of a p-n junction.…”

Section: Experimental Data and Theorymentioning

confidence: 93%

Effect of n^--layer thickness on green-light-emitting efficiency in nitrogen-doped GaP grown by liquid phase epitaxy

Chen

Ding

Dong

2000

J. Phys. D: Appl. Phys.

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By comparing the photoluminescence intensity of a p-type crystal with that of a n-type crystal, we find that the p-side is the main light-emitting region in the double-n structure nitrogen-doped GaP (GaP:N) material grown by liquid phase epitaxy (LPE). From this experimental result, we have created a simple theory regarding the minority-carrier-current distribution in the lower donor concentration layer in the double n-structure GaP:N material. The theory describes that the interface of the lower, n-, and the higher, n+, donor concentration LPE n-layers has a reflection effect on the holes diffusing from p- to n-type crystal. When we decrease the thickness of the n--layer and the majority-carrier concentration ratio of the n-- and n+-layers, the electron injection efficiency increases and the photoluminescence is correspondingly enhanced.

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Very High Efficiency GaP Green Light Emitting Diodes

Cited by 19 publications

References 16 publications

Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Effect of dislocations on green electroluminescence efficiency in GaP grown by liquid phase epitaxy

Effect of n^--layer thickness on green-light-emitting efficiency in nitrogen-doped GaP grown by liquid phase epitaxy

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Very High Efficiency GaP Green Light Emitting Diodes

Cited by 19 publications

References 16 publications

Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Oxygen Gettering in Green GaP : N LED's Grown by Overcompensated LPE

Effect of dislocations on green electroluminescence efficiency in GaP grown by liquid phase epitaxy

Effect of n--layer thickness on green-light-emitting efficiency in nitrogen-doped GaP grown by liquid phase epitaxy

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Effect of n^--layer thickness on green-light-emitting efficiency in nitrogen-doped GaP grown by liquid phase epitaxy