N‐Type Surface Doping of MAPbI 3 via Charge Transfer from Small Molecules

Organic hole and electron transport materials are regularly employed as electron‐ and hole‐blocking layers in perovskite thin‐film solar cells. In order to optimize charge extraction in the device, these organic layers can be doped using organic small molecules. However, to date there is little work...

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Published in:	Advanced electronic materials Vol. 4; no. 7
Main Authors:	Perry, Erin E., Labram, John G., Venkatesan, Naveen R., Nakayama, Hidenori, Chabinyc, Michael L.
Format:	Journal Article
Language:	English
Published:	United States Wiley 01-07-2018
Subjects:	Materials Science Physics Science & Technology - Other Topics
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Abstract	Organic hole and electron transport materials are regularly employed as electron‐ and hole‐blocking layers in perovskite thin‐film solar cells. In order to optimize charge extraction in the device, these organic layers can be doped using organic small molecules. However, to date there is little work carried out on direct doping of perovskite surfaces. In this report, the change in electrical properties of thin films of MAPbI 3 by surface doping the film with an organic dopant molecule: cobaltocene (Co(C 5 H 5 ) 2 ) is studied. By varying the quantity of cobaltocene deposited, the conductivity of MAPbI 3 thin films is observed to be tunable over several orders of magnitude. A tunable shift in the Fermi level illustrating that charge transfer doping enables control over the interfacial energy levels, is observed. An increase in photoconductivity is seen at intermediate doping levels, indicating passivation of surface traps confirmed by increased photoluminescence. This model system provides a means to understand more complex heterointerfaces of doped organic blends at perovskite surfaces.
AbstractList	Not provided. Organic hole and electron transport materials are regularly employed as electron‐ and hole‐blocking layers in perovskite thin‐film solar cells. In order to optimize charge extraction in the device, these organic layers can be doped using organic small molecules. However, to date there is little work carried out on direct doping of perovskite surfaces. In this report, the change in electrical properties of thin films of MAPbI 3 by surface doping the film with an organic dopant molecule: cobaltocene (Co(C 5 H 5 ) 2 ) is studied. By varying the quantity of cobaltocene deposited, the conductivity of MAPbI 3 thin films is observed to be tunable over several orders of magnitude. A tunable shift in the Fermi level illustrating that charge transfer doping enables control over the interfacial energy levels, is observed. An increase in photoconductivity is seen at intermediate doping levels, indicating passivation of surface traps confirmed by increased photoluminescence. This model system provides a means to understand more complex heterointerfaces of doped organic blends at perovskite surfaces.
Author	Venkatesan, Naveen R. Chabinyc, Michael L. Nakayama, Hidenori Perry, Erin E. Labram, John G.
Author_xml	– sequence: 1 givenname: Erin E. surname: Perry fullname: Perry, Erin E. organization: Materials Department University of California, Santa Barbara Santa Barbara CA 93106 USA – sequence: 2 givenname: John G. orcidid: 0000-0001-6562-9895 surname: Labram fullname: Labram, John G. organization: Materials Department University of California, Santa Barbara Santa Barbara CA 93106 USA – sequence: 3 givenname: Naveen R. surname: Venkatesan fullname: Venkatesan, Naveen R. organization: Materials Department University of California, Santa Barbara Santa Barbara CA 93106 USA – sequence: 4 givenname: Hidenori surname: Nakayama fullname: Nakayama, Hidenori organization: Yokohama R&D Center Mitsubishi Chemical Corporation 1000 Kamoshida‐cho, Aoba‐ku Yokohama‐shi Kanagawa 227‐8502 Japan, Mitsubishi Chemical – Center for Advanced Materials University of California, Santa Barbara Santa Barbara CA 93106 USA – sequence: 5 givenname: Michael L. orcidid: 0000-0003-4641-3508 surname: Chabinyc fullname: Chabinyc, Michael L. organization: Materials Department University of California, Santa Barbara Santa Barbara CA 93106 USA
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Snippet	Organic hole and electron transport materials are regularly employed as electron‐ and hole‐blocking layers in perovskite thin‐film solar cells. In order to... Not provided.
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Title	N‐Type Surface Doping of MAPbI 3 via Charge Transfer from Small Molecules
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