Title :
Stability of microcrystalline silicon for thin film solar cell applications
Author :
Finger, F. ; Carius, R. ; Dylla, T. ; Klein, S. ; Okur, S. ; Günes, M.
Abstract :
The development of microcrystalline silicon (μc-Si:H) for solar cells has made good progress with efficiencies better than those of amorphous silicon (a-Si:H) devices. Of particular interest is the absence of light-induced degradation in highly crystalline μc-Si:H. However, the highest efficiencies are obtained with material which may still include a-Si:H regions and light-induced changes may be expected in such material. On the other hand, material of high crystallinity is susceptible to in-diffusion of atmospheric gases which, through adsorption or oxidation, affect the electronic transport. Investigations are presented of such effects concerning the stability of μc-Si:H films and solar cells prepared by plasma-enhanced chemical vapour deposition and hot wire chemical vapour deposition
Keywords :
chemical vapour deposition <microcrystalline Si for thin film solar cell appls., stabil.>; elemental semiconductors <microcrystalline Si for thin film solar cell appls., stabil.>; oxidation <microcrystalline Si for thin film solar cell appls., stabil.>; plasma CVD <microcrystalline Si for thin film solar cell appls., stabil.>; silicon <microcrystalline Si for thin film solar cell appls., stabil.>; solar cells <microcrystalline Si for thin film solar cell appls., stabil.>; μc-Si:H; Si:H; adsorption; hot wire chemical vapour deposition; light-induced degradation; microcrystalline silicon; oxidation; plasma-enhanced chemical vapour deposition; thin film solar cell applications;
Journal_Title :
Circuits, Devices and Systems, IEE Proceedings -
DOI :
10.1049/ip-cds:20030636
