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Impact of interfacial molecular orientation on radiative recombination and charge generation efficiency

  • A long standing question in organic electronics concerns the effects of molecular orientation at donor/acceptor heterojunctions. Given a well-controlled donor/acceptor bilayer system, we uncover the genuine effects of molecular orientation on charge generation and recombination. These effects are studied through the point of view of photovoltaics-however, the results have important implications on the operation of all optoelectronic devices with donor/ acceptor interfaces, such as light emitting diodes and photodetectors. Our findings can be summarized by two points. First, devices with donor molecules face-on to the acceptor interface have a higher charge transfer state energy and less non-radiative recombination, resulting in larger open-circuit voltages and higher radiative efficiencies. Second, devices with donor molecules edge-on to the acceptor interface are more efficient at charge generation, attributed to smaller electronic coupling between the charge transfer states and the ground state, and lower activation energy forA long standing question in organic electronics concerns the effects of molecular orientation at donor/acceptor heterojunctions. Given a well-controlled donor/acceptor bilayer system, we uncover the genuine effects of molecular orientation on charge generation and recombination. These effects are studied through the point of view of photovoltaics-however, the results have important implications on the operation of all optoelectronic devices with donor/ acceptor interfaces, such as light emitting diodes and photodetectors. Our findings can be summarized by two points. First, devices with donor molecules face-on to the acceptor interface have a higher charge transfer state energy and less non-radiative recombination, resulting in larger open-circuit voltages and higher radiative efficiencies. Second, devices with donor molecules edge-on to the acceptor interface are more efficient at charge generation, attributed to smaller electronic coupling between the charge transfer states and the ground state, and lower activation energy for charge generation.show moreshow less

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Author details:Niva A. Ran, Steffen RolandORCiDGND, John A. Love, Victoria Savikhin, Christopher J. Takacs, Yao-Tsung Fu, Hong Li, Veaceslav Coropceanu, Xiaofeng LiuORCiD, Jean-Luc Bredas, Guillermo C. Bazan, Michael F. Toney, Dieter NeherORCiDGND, Thuc-Quyen Nguyen
DOI:https://doi.org/10.1038/s41467-017-00107-4
ISSN:2041-1723
Pubmed ID:https://pubmed.ncbi.nlm.nih.gov/28724989
Title of parent work (English):Nature Communications
Publisher:Nature Publ. Group
Place of publishing:London
Publication type:Article
Language:English
Year of first publication:2017
Publication year:2017
Release date:2020/04/20
Volume:8
Number of pages:9
Funding institution:Department of the Navy, Office of Naval Research [N00014-14-1-0580]; MRSEC Program of the NSF [DMR 1121053]; NSF; German Ministry of Science and Education (Project UNVEIL) [FKZ 13N13719]; Deutsche Forschungsgesellschaft [INST 336/94-1 FUGG]
Organizational units:Mathematisch-Naturwissenschaftliche Fakultät / Institut für Physik und Astronomie
Peer review:Referiert

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