Metal Matrix Composite Solar Cell Metallization

Metal Matrix Composite Solar Cell Metallization

Advanced solar cells are moving to ever thinner formats in order to save mass and in some cases improve performance. As cells are thinned, the possibility that they may fracture or cleave due to mechanical stresses is increased. Fractures of the cell can degrade the overall device performance if the...

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Main Authors: Wilt David M., Bradshaw Geoffrey, Gap Lt. Nathan, Abudayyeh Omar K., Nelson Cayla, Han Sang, Cox Nathanael, Rape Aaron, Landi Brian, Whipple Steve
Format: Article
Language:English
Published: EDP Sciences 2017-01-01
Series:E3S Web of Conferences
Online Access:https://doi.org/10.1051/e3sconf/20171603001
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spelling doaj-020387db62924384b9cf40763bc5bc952021-04-02T14:09:09ZengEDP SciencesE3S Web of Conferences2267-12422017-01-01160300110.1051/e3sconf/20171603001e3sconf_espc2017_03001Metal Matrix Composite Solar Cell MetallizationWilt David M.0Bradshaw Geoffrey1Gap Lt. Nathan2Abudayyeh Omar K.3Nelson Cayla4Han Sang5Cox Nathanael6Rape Aaron7Landi Brian8Whipple Steve9Space Vehicles Directorate, Air Force Research LaboratorySpace Vehicles Directorate, Air Force Research LaboratorySpace Vehicles Directorate, Air Force Research LaboratoryThe University of New MexicoThe University of New MexicoThe University of New MexicoRochester Institute of TechnologyRochester Institute of TechnologyRochester Institute of TechnologySolAero Technologies CorpAdvanced solar cells are moving to ever thinner formats in order to save mass and in some cases improve performance. As cells are thinned, the possibility that they may fracture or cleave due to mechanical stresses is increased. Fractures of the cell can degrade the overall device performance if the fracture propagates through the contact metallization, which frequently occurs. To address this problem, a novel semiconductor metallization system based on multi-walled carbon nanotube (CNT) reinforcement, termed metal matrix composite (MMC) metallization is under investigation. Electro-mechanical characterization of MMC films demonstrate their ability to provide electrical conductivity over >40 micron wide cracks in the underlying semiconductor, with the carbon nanotubes bridging the gap. In addition, these materials show a “self-healing” behaviour, electrically reconnecting at ~30 microns when strained past failure. Triple junction (TJ) space cells with MMC metallization demonstrated no loss in Jsc after intentional fracture, whereas TJ cells with conventional metallization suffer up to 50% Jsc loss.https://doi.org/10.1051/e3sconf/20171603001
collection DOAJ
language English
format Article
sources DOAJ
author Wilt David M.
Bradshaw Geoffrey
Gap Lt. Nathan
Abudayyeh Omar K.
Nelson Cayla
Han Sang
Cox Nathanael
Rape Aaron
Landi Brian
Whipple Steve
spellingShingle Wilt David M.
Bradshaw Geoffrey
Gap Lt. Nathan
Abudayyeh Omar K.
Nelson Cayla
Han Sang
Cox Nathanael
Rape Aaron
Landi Brian
Whipple Steve
Metal Matrix Composite Solar Cell Metallization
E3S Web of Conferences
author_facet Wilt David M.
Bradshaw Geoffrey
Gap Lt. Nathan
Abudayyeh Omar K.
Nelson Cayla
Han Sang
Cox Nathanael
Rape Aaron
Landi Brian
Whipple Steve
author_sort Wilt David M.
title Metal Matrix Composite Solar Cell Metallization
title_short Metal Matrix Composite Solar Cell Metallization
title_full Metal Matrix Composite Solar Cell Metallization
title_fullStr Metal Matrix Composite Solar Cell Metallization
title_full_unstemmed Metal Matrix Composite Solar Cell Metallization
title_sort metal matrix composite solar cell metallization
publisher EDP Sciences
series E3S Web of Conferences
issn 2267-1242
publishDate 2017-01-01
description Advanced solar cells are moving to ever thinner formats in order to save mass and in some cases improve performance. As cells are thinned, the possibility that they may fracture or cleave due to mechanical stresses is increased. Fractures of the cell can degrade the overall device performance if the fracture propagates through the contact metallization, which frequently occurs. To address this problem, a novel semiconductor metallization system based on multi-walled carbon nanotube (CNT) reinforcement, termed metal matrix composite (MMC) metallization is under investigation. Electro-mechanical characterization of MMC films demonstrate their ability to provide electrical conductivity over >40 micron wide cracks in the underlying semiconductor, with the carbon nanotubes bridging the gap. In addition, these materials show a “self-healing” behaviour, electrically reconnecting at ~30 microns when strained past failure. Triple junction (TJ) space cells with MMC metallization demonstrated no loss in Jsc after intentional fracture, whereas TJ cells with conventional metallization suffer up to 50% Jsc loss.
url https://doi.org/10.1051/e3sconf/20171603001
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AT coxnathanael metalmatrixcompositesolarcellmetallization
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AT landibrian metalmatrixcompositesolarcellmetallization
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