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

Andrew Findlay; Jacek Lagowski; Marshall Wilson; John D'Amico; Alexandre Savtchouk; Ferenc Korsos; György Nadudvari

doi:10.4028/www.scientific.net/SSP.205-206.128

Paper Titles

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
p.136

A Comparison of EBIC, LBIC and XBIC Methods as Tools for Multicrystalline Si Characterization
p.142

Properties of Point Defects in Silicon: New Results after a Long-Time Debate
p.151

Fast and Slow Vacancies in Silicon
p.157

HomeSolid State PhenomenaSolid State Phenomena Vols. 205-206Inline PL Inspection and Advanced Offline...

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

Abstract:

Recently introduced techniques for whole wafer mapping and imaging create new possibilities for root cause analysis of emitter passivation defects. Inline compatible PL imaging identifies such defects as localized regions with increased emitter saturation current and reduced implied open circuit voltage. Advanced offline evaluation of defective areas can be then performed with multiparameter noncontact measurements capable to establish the role of surface recombination, the interface trap density, or the dielectric charge that controls the field-effect passivation. The relevant novel metrologies are discussed and are illustrated using examples of advanced silicon passivation by dielectric films and by a-Si heterojunction structures.

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Periodical:

Solid State Phenomena (Volumes 205-206)

Pages:

128-135

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.205-206.128

Citation:

Cite this paper

Online since:

October 2013

Authors:

Andrew Findlay, Jacek Lagowski, Marshall Wilson, John D'Amico, Alexandre Savtchouk, Ferenc Korsos, György Nadudvari

Keywords:

Corona Charge, Microwave, Passivation Defects, Photoconductance Decay, Photoluminescence Imaging, Quasisteady State

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