Overview and Latest Developments in Photoconductance Lifetime Measurements in Silicon

Ronald A. Sinton; Adrienne L. Blum; James S. Swirhun

doi:10.4028/www.scientific.net/SSP.205-206.103

Paper Titles

Analysis of Inhomogeneous Dislocation Distribution in Multicrystalline Si
p.77

Properties of Strong Luminescence at 0.93 eV in Solar Grade Silicon
p.83

10 cm Diameter Mono Cast Si Growth and its Characterization
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Characterization of Residual Strain in Si Ingots Grown by the Seed-Cast Method
p.94

Overview and Latest Developments in Photoconductance Lifetime Measurements in Silicon
p.103

Efficiency-Limiting Recombination in Multicrystalline Silicon Solar Cells
p.110

Photoluminescence Imaging of Silicon Bricks
p.118

Inline PL Inspection and Advanced Offline Evaluation of Passivation Defects, Charge and Interfaces
p.128

Transition Metal Precipitates in Mc Si: A New Detection Method Using 3D-FIB
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HomeSolid State PhenomenaSolid State Phenomena Vols. 205-206Overview and Latest Developments in...

Overview and Latest Developments in Photoconductance Lifetime Measurements in Silicon

Abstract:

Photoconductance measurements have been one of the most common ways to measure the lifetime in silicon for over 60 years. Since 1985, the most common method for doing calibrated lifetime measurements is using an eddy-current sensor to monitor photoconductance as a function of time and illumination, providing data that can be interpreted in terms of carrier density and hence lifetime. Here we present recent extensions to this measurement technique that have generalized the method. Bulk lifetime measurements on industrial samples are presented. The information available from the effects of grain boundaries on eddy-current measurements are summarized. Recent applications for the use of these instruments for measurement of mobility in compensated materials are also described.

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Periodical:

Solid State Phenomena (Volumes 205-206)

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103-109

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.205-206.103

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Online since:

October 2013

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Ronald A. Sinton, Adrienne L. Blum, James S. Swirhun

Keywords:

Lifetime, Mobility, QSSPC

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References

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