Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells

10.1038/s41467-018-05200-w

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Main Authors:	Tan J.-K., Png R.-Q., Zhao C., Ho P.K.H.
Other Authors:	DEPT OF PHYSICS
Format:	Article
Published:	Nature Publishing Group 2020
Subjects:	thiophene derivative electricity fuel cell performance assessment photovoltaic system solar power thermodynamics Article current density electric potential electric resistance fermion solar energy ultraviolet photoelectron spectroscopy
Online Access:	https://scholarbank.nus.edu.sg/handle/10635/174209
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Institution:	National University of Singapore

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spelling	sg-nus-scholar.10635-1742092024-11-15T21:57:17Z Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells Tan J.-K. Png R.-Q. Zhao C. Ho P.K.H. DEPT OF PHYSICS thiophene derivative electricity fuel cell performance assessment photovoltaic system solar power thermodynamics Article current density electric potential electric resistance fermion solar energy thermodynamics ultraviolet photoelectron spectroscopy 10.1038/s41467-018-05200-w Nature Communications 9 1 3269 2020-09-04T01:46:40Z 2020-09-04T01:46:40Z 2018 Article Tan J.-K., Png R.-Q., Zhao C., Ho P.K.H. (2018). Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells. Nature Communications 9 (1) : 3269. ScholarBank@NUS Repository. https://doi.org/10.1038/s41467-018-05200-w 2041-1723 https://scholarbank.nus.edu.sg/handle/10635/174209 Nature Publishing Group Unpaywall 20200831
institution	National University of Singapore
building	NUS Library
continent	Asia
country	Singapore Singapore
content_provider	NUS Library
collection	ScholarBank@NUS
topic	thiophene derivative electricity fuel cell performance assessment photovoltaic system solar power thermodynamics Article current density electric potential electric resistance fermion solar energy thermodynamics ultraviolet photoelectron spectroscopy
spellingShingle	thiophene derivative electricity fuel cell performance assessment photovoltaic system solar power thermodynamics Article current density electric potential electric resistance fermion solar energy thermodynamics ultraviolet photoelectron spectroscopy Tan J.-K. Png R.-Q. Zhao C. Ho P.K.H. Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
description	10.1038/s41467-018-05200-w
author2	DEPT OF PHYSICS
author_facet	DEPT OF PHYSICS Tan J.-K. Png R.-Q. Zhao C. Ho P.K.H.
format	Article
author	Tan J.-K. Png R.-Q. Zhao C. Ho P.K.H.
author_sort	Tan J.-K.
title	Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
title_short	Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
title_full	Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
title_fullStr	Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
title_full_unstemmed	Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
title_sort	ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells
publisher	Nature Publishing Group
publishDate	2020
url	https://scholarbank.nus.edu.sg/handle/10635/174209
_version_	1821234615666343936

Ohmic transition at contacts key to maximizing fill factor and performance of organic solar cells

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