Hyperspectral photoluminescence imaging of defects in solar cells

Hyperspectral photoluminescence imaging of defects in solar cells

The present work is a demonstration of how near infrared (NIR) hyperspectral photoluminescence imaging can be used to detect defects in silicon wafers and solar cells. Chemometric analysis techniques such as multivariate curve resolution (MCR) and partial least squares discriminant analysis (PLS-DA)...

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Main Authors: Ingunn Burud, Torbjørn Mehl, Andreas Flo, Dominik Lausch, Espen Olsen
Format: Article
Language:English
Published: IM Publications Open 2016-12-01
Series:Journal of Spectral Imaging
Subjects:
near infrared
photovoltaic
multicrystalline silicon
MCR
PLS-DA
Online Access:https://www.impublications.com/download.php?code=I05_a8
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spelling doaj-6ad7559510824a50a062178052eb10102020-11-24T21:19:16ZengIM Publications OpenJournal of Spectral Imaging2040-45652040-45652016-12-015a810.1255/jsi.2016.a8Hyperspectral photoluminescence imaging of defects in solar cellsIngunn Burud0Torbjørn Mehl1Andreas Flo2Dominik Lausch3Espen Olsen4Norwegian University of Life Sciences, Department of Mathematical Sciences and Technology, Campus Ås, Pb 5003, 1433 Ås, NorwayNorwegian University of Life Sciences, Department of Mathematical Sciences and Technology, Campus Ås, Pb 5003, 1433 Ås, NorwayNorwegian University of Life Sciences, Department of Mathematical Sciences and Technology, Campus Ås, Pb 5003, 1433 Ås, NorwayFraunhofer-Center für Silizium Photovoltaik CSP Otto-Eißfeldt-Straße 12, 06120 Halle (Saale), GermanyNorwegian University of Life Sciences, Department of Mathematical Sciences and Technology, Campus Ås, Pb 5003, 1433 Ås, NorwayThe present work is a demonstration of how near infrared (NIR) hyperspectral photoluminescence imaging can be used to detect defects in silicon wafers and solar cells. Chemometric analysis techniques such as multivariate curve resolution (MCR) and partial least squares discriminant analysis (PLS-DA) allow various types of defects to be classified and cascades of radiative defects in the samples to be extracted. It is also demonstrated how utilising a macro lens yields a spatial resolution of 30 µm on selected regions of the samples, revealing that some types of defect signals originate in grain boundaries of the silicon crystal, whereas other signals show up as singular spots. Combined with independent investigation techniques, hyperspectral imaging is a promising tool for determining origins of defects in silicon samples for photovoltaic applications.https://www.impublications.com/download.php?code=I05_a8near infraredphotovoltaicmulticrystalline siliconMCRPLS-DA
collection DOAJ
language English
format Article
sources DOAJ
author Ingunn Burud
Torbjørn Mehl
Andreas Flo
Dominik Lausch
Espen Olsen
spellingShingle Ingunn Burud
Torbjørn Mehl
Andreas Flo
Dominik Lausch
Espen Olsen
Hyperspectral photoluminescence imaging of defects in solar cells
Journal of Spectral Imaging
near infrared
photovoltaic
multicrystalline silicon
MCR
PLS-DA
author_facet Ingunn Burud
Torbjørn Mehl
Andreas Flo
Dominik Lausch
Espen Olsen
author_sort Ingunn Burud
title Hyperspectral photoluminescence imaging of defects in solar cells
title_short Hyperspectral photoluminescence imaging of defects in solar cells
title_full Hyperspectral photoluminescence imaging of defects in solar cells
title_fullStr Hyperspectral photoluminescence imaging of defects in solar cells
title_full_unstemmed Hyperspectral photoluminescence imaging of defects in solar cells
title_sort hyperspectral photoluminescence imaging of defects in solar cells
publisher IM Publications Open
series Journal of Spectral Imaging
issn 2040-4565
2040-4565
publishDate 2016-12-01
description The present work is a demonstration of how near infrared (NIR) hyperspectral photoluminescence imaging can be used to detect defects in silicon wafers and solar cells. Chemometric analysis techniques such as multivariate curve resolution (MCR) and partial least squares discriminant analysis (PLS-DA) allow various types of defects to be classified and cascades of radiative defects in the samples to be extracted. It is also demonstrated how utilising a macro lens yields a spatial resolution of 30 µm on selected regions of the samples, revealing that some types of defect signals originate in grain boundaries of the silicon crystal, whereas other signals show up as singular spots. Combined with independent investigation techniques, hyperspectral imaging is a promising tool for determining origins of defects in silicon samples for photovoltaic applications.
topic near infrared
photovoltaic
multicrystalline silicon
MCR
PLS-DA
url https://www.impublications.com/download.php?code=I05_a8
work_keys_str_mv AT ingunnburud hyperspectralphotoluminescenceimagingofdefectsinsolarcells
AT torbjørnmehl hyperspectralphotoluminescenceimagingofdefectsinsolarcells
AT andreasflo hyperspectralphotoluminescenceimagingofdefectsinsolarcells
AT dominiklausch hyperspectralphotoluminescenceimagingofdefectsinsolarcells
AT espenolsen hyperspectralphotoluminescenceimagingofdefectsinsolarcells
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