Title :
A novel, nondestructive, technique using EBIC to determine diffusion lengths in GaAs solar cells
Author_Institution :
EEV Ltd., Chelmsford, UK
Abstract :
A nondestructive technique for measuring minority carrier diffusion lengths in GaAs and other single crystal solar cells is described. The technique relies on the measurement of EBIC (electron beam induced current) from a cell. As the primary beam voltage is varied, the penetration depth of the beam changes. Using a Monte-Carlo simulation of the carrier generation produced by the beam, and solving the minority carrier continuity equation, one can model the current collection. Adjusting the diffusion lengths used in the model, to fit the experimental data, one can determine, with good accuracy, diffusion lengths in the actual device. The technique has been applied to as-made and irradiated cells and used to determine material degradation coefficients
Keywords :
EBIC; III-V semiconductors; Monte Carlo methods; carrier lifetime; electron beam effects; gallium arsenide; minority carriers; nondestructive testing; proton effects; semiconductor device models; solar cells; EBIC; GaAs; GaAs solar cells; Monte-Carlo simulation; carrier generation; current collection; electron beam induced current; electron radiation; irradiated cells; material degradation coefficients; minority carrier continuity equation; minority carrier diffusion lengths; nondestructive technique; proton radiation; single crystal solar cells; Acceleration; Electron beams; Gallium arsenide; Length measurement; Numerical analysis; Optical scattering; Particle beams; Photovoltaic cells; Solar power generation; Voltage;
Conference_Titel :
Photovoltaic Specialists Conference, 1996., Conference Record of the Twenty Fifth IEEE
Conference_Location :
Washington, DC
Print_ISBN :
0-7803-3166-4
DOI :
10.1109/PVSC.1996.563989
