Title :
Improving silicon light emitting devices using Kirchhoff´s law
Author :
Trupke, T. ; Zhao, J. ; Wang, A. ; Green, M.A.
Author_Institution :
Centre for Third Generation Photovoltaics, New South Wales Univ., Sydney, NSW, Australia
Abstract :
An analytical relation between the internal- and the external luminescence quantum efficiency of textured silicon wafers is derived using a generalisation of Kirchhoff s law. We show that only a fraction of one third of internally generated photons can escape a textured 450 μm thick silicon wafer even under the idealising assumption of negligible free carrier absorption, the major fraction of photons being reabsorbed by band-band-transitions. Surprisingly high external luminescence quantum efficiencies up to 0.6% at room temperature of silicon light emitting diodes have been published recently. From our theoretical model we can conclude that further significant improvements of the external luminescence quantum efficiency of silicon devices can be achieved by optimising the thickness of the devices, the texturing and the passivation of the surfaces texturing.
Keywords :
electroluminescence; elemental semiconductors; light emitting diodes; passivation; silicon; surface texture; 0.6 percent; 25 degC; 450 mum; Kirchhoff law; Si; analytical relation; band-band-transitions; external luminescence quantum efficiency; free carrier absorption; internal luminescence quantum efficiency; internally generated photons; passivation; room temperature; silicon light emitting devices; silicon light emitting diodes; surfaces texturing; textured 450 μm thick silicon wafer; textured silicon wafers; thickness optimisation; Absorption; Kirchhoff´s Law; Light emitting diodes; Luminescence; Passivation; Quantum mechanics; Semiconductor device modeling; Silicon devices; Surface texture; Temperature;
Conference_Titel :
Optoelectronic and Microelectronic Materials and Devices, 2002 Conference on
Print_ISBN :
0-7803-7571-8
DOI :
10.1109/COMMAD.2002.1237242
