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Vapor Deposition of GaP for High-Efficiency Yellow Solid-State Lamps
Bruce W. Wessels
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Corresponding author for this work
Materials Science and Engineering
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Article
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peer-review
24
Scopus citations
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Keyphrases
Chemical Vapor Deposition
33%
Diode
100%
Diode Reverse Recovery
33%
Electroluminescence
66%
Epitaxial
33%
Epitaxial Layers
33%
Ga Vacancy
33%
Gallium
33%
Gallium Phosphide
33%
Heat Source Temperature
33%
High Efficiency
100%
Hydrogen Chloride
33%
Increased Nitrogen
33%
Lamp
100%
Long Wavelength
33%
Mesostructure
33%
Minority Carrier Lifetime
66%
Nitrogen Doping
33%
Nitrogen Incorporation
33%
Phosphine
33%
Pulsed Operation
33%
Quantum Efficiency
33%
Reactant Concentration
33%
Recombination Centers
33%
Recovery Method
33%
Solid State
100%
Substrate Temperature
33%
Temperature Concentration
33%
Vacancy Complexes
33%
Vapor Deposition
100%
Yellow Light-emitting Diodes
33%
Engineering
Carrier Lifetime
100%
Chemical Vapor Deposition
50%
Epitaxial Layer
50%
Ga Vacancy
50%
Light-Emitting Diode
50%
Minority Carriers
100%
Quantum Efficiency
50%
Reactant
50%
Reactant Concentration
50%
Recombination Centre
50%
Recovery Technique
50%
Substrate Temperature
50%
Vapor Deposition
100%
Material Science
Carrier Lifetime
100%
Chemical Vapor Deposition
50%
Electroluminescence
100%
Epitaxial Layer
50%
Gallium
100%
Lamp
100%
Light-Emitting Diode
50%