Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer

10.1504/IJNT.2014.059833

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Bibliographic Details
Main Authors:	Elumalai, N.K., Vijila, C., Jose, R., Jie, Z., Ramakrishna, S.
Other Authors:	MECHANICAL ENGINEERING
Format:	Article
Published:	2014
Subjects:	Charge transport Electron selective layer Solution processed Temperature dependence Trap depth Zinc oxide
Online Access:	http://scholarbank.nus.edu.sg/handle/10635/85069
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Institution:	National University of Singapore

id	sg-nus-scholar.10635-85069
record_format	dspace
spelling	sg-nus-scholar.10635-850692024-11-08T19:59:56Z Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer Elumalai, N.K. Vijila, C. Jose, R. Jie, Z. Ramakrishna, S. MECHANICAL ENGINEERING Charge transport Electron selective layer Solution processed Temperature dependence Trap depth Zinc oxide 10.1504/IJNT.2014.059833 International Journal of Nanotechnology 11 1-4 322-332 2014-10-07T09:03:37Z 2014-10-07T09:03:37Z 2014 Article Elumalai, N.K., Vijila, C., Jose, R., Jie, Z., Ramakrishna, S. (2014). Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer. International Journal of Nanotechnology 11 (1-4) : 322-332. ScholarBank@NUS Repository. https://doi.org/10.1504/IJNT.2014.059833 14757435 http://scholarbank.nus.edu.sg/handle/10635/85069 000333193300029 Scopus
institution	National University of Singapore
building	NUS Library
continent	Asia
country	Singapore Singapore
content_provider	NUS Library
collection	ScholarBank@NUS
topic	Charge transport Electron selective layer Solution processed Temperature dependence Trap depth Zinc oxide
spellingShingle	Charge transport Electron selective layer Solution processed Temperature dependence Trap depth Zinc oxide Elumalai, N.K. Vijila, C. Jose, R. Jie, Z. Ramakrishna, S. Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
description	10.1504/IJNT.2014.059833
author2	MECHANICAL ENGINEERING
author_facet	MECHANICAL ENGINEERING Elumalai, N.K. Vijila, C. Jose, R. Jie, Z. Ramakrishna, S.
format	Article
author	Elumalai, N.K. Vijila, C. Jose, R. Jie, Z. Ramakrishna, S.
author_sort	Elumalai, N.K.
title	Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
title_short	Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
title_full	Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
title_fullStr	Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
title_full_unstemmed	Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer
title_sort	effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured zno as electron buffer layer
publishDate	2014
url	http://scholarbank.nus.edu.sg/handle/10635/85069
_version_	1821182629193449472

Effect of trap depth and interfacial energy barrier on charge transport in inverted organic solar cells employing nanostructured ZnO as electron buffer layer

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