Title :
Proton radiation damage at low temperature in GaAs and GaN light-emitting diodes
Author :
Khanna, Shyam M. ; Estan, Diego ; Houdayer, Alain ; Liu, Hui C. ; Dudek, Richard
Author_Institution :
Defence R&D Canada, Ottawa, Ont., Canada
Abstract :
It is shown that the radiation hardness for light emission in light-emitting diodes (LEDs) is substantially improved at low temperatures. This is demonstrated through measurements of light emission at room and low temperatures from amphoteric Si-doped gallium arsenide, gallium arsenide quantum well and gallium nitride quantum well LEDs following proton irradiation at room and low temperatures. The enhanced low-temperature radiation hardness for light emission in these LEDs is explained in terms of an improvement in radiative efficiency due to a reduction of nonradiative transition probability at low temperatures. Further, lattice displacement damage in these devices due to irradiation at room temperature is compared with the corresponding damage at low temperatures. Our results show that the amount of lattice damage is dependent on irradiation temperature.
Keywords :
III-V semiconductors; gallium arsenide; gallium compounds; light emitting diodes; proton effects; semiconductor doping; semiconductor quantum wells; silicon; 293 to 298 K; GaAs; GaAs:Si; GaN; GaN:Si; LEDs; amphoteric Si-doped gallium arsenide; displacement damage; gallium arsenide quantum well LEDs; gallium nitride quantum well LEDs; irradiation temperature; lattice damage; lattice displacement damage; light emission; light-emitting diodes; low temperature; low temperatures; nonradiative transition probability; proton irradiation; proton radiation damage; radiation efficiency; radiation hardness; Gallium arsenide; Gallium nitride; III-V semiconductor materials; Lattices; Light emitting diodes; Neutrons; Power generation; Protons; Stimulated emission; Temperature;
Journal_Title :
Nuclear Science, IEEE Transactions on
DOI :
10.1109/TNS.2004.839105
