Quantum efficiency and formation of the emission line in light-emitting diodes based on InGaN/GaN quantum well structures

Quantum efficiency and formation of the emission line in light-emitting diodes based on InGaN/GaN quantum well structures

The spectra of electroluminescence, photoluminescence, and photocurrent for the In{sub 0.2}Ga{sub 0.8}N/GaN quantum-well structures are studied to clarify the causes for the reduction in quantum efficiency with increasing forward current. It is established that the quantum efficiency decreases as th...

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Bibliographic Details
Published in:Semiconductors (Woodbury, N.Y.) Vol. 41; no. 1; pp. 87 - 93
Main Authors: Bochkareva, N. I., Tarkhin, D. V., Rebane, Yu. T., Gorbunov, R. I., Lelikov, Yu. S., Martynov, I. A., Shreter, Yu. G.
Format: Journal Article
Language:English
Published: United States 01-01-2007
Subjects:
ELECTROLUMINESCENCE
EV RANGE 01-10
GALLIUM NITRIDES
INDIUM NITRIDES
LIGHT EMITTING DIODES
MATERIALS SCIENCE
PHOTOLUMINESCENCE
QUANTUM EFFICIENCY
QUANTUM WELLS
SPECTRA
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Summary:The spectra of electroluminescence, photoluminescence, and photocurrent for the In{sub 0.2}Ga{sub 0.8}N/GaN quantum-well structures are studied to clarify the causes for the reduction in quantum efficiency with increasing forward current. It is established that the quantum efficiency decreases as the emitting photon energy approaches the mobility edge in the In{sub 0.2}Ga{sub 0.8}N layer. The mobility edge determined from the photocurrent spectra is E{sub me} = 2.89 eV. At the photon energies hv > 2.69 eV, the charge carriers can tunnel to nonradiative recombination centers with a certain probability, and therefore, the quantum efficiency decreases. The tunnel injection into deep localized states provides the maximum electroluminescence efficiency. This effect is responsible for the origin of the characteristic maximum in the quantum efficiency of the emitting diodes at current densities much lower than the operating densities. Occupation of the deep localized states in the density-of-states 'tails' in InGaN plays a crucial role in the formation of the emission line as well. It is shown that the increase in the quantum efficiency and the 'red' shift of the photoluminescence spectra with the voltage correlate with the changes in the photocurrent and occur due to suppression of the separation of photogenerated carriers in the field of the space charge region and to their thermalization to deep local states.
ISSN:1063-7826
1090-6479
DOI:10.1134/S1063782607010174