Transient photovoltaic behavior of air-stable, inverted organic solar cells with solution-processed electron transport layer

Chang Su Kim; Stephanie S. Lee; Enrique D. Gomez; Jong Bok Kim; Yueh Lin Loo

doi:10.1063/1.3099947

Transient photovoltaic behavior of air-stable, inverted organic solar cells with solution-processed electron transport layer

Chang Su Kim
, Stephanie S. Lee
, Enrique D. Gomez
, Jong Bok Kim
, Yueh Lin Loo

Research output: Contribution to journal › Article › peer-review

158 Scopus citations

Abstract

The short-circuit current density of inverted organic solar cells comprising a solution-processed titania electron transport layer increases with continuous illumination in air and saturates after 10 min. On extended exposure (>2 days), the open-circuit voltage of the devices increases also. The improvement in device characteristics over short time scales is attributed to the filling of shallow electron traps in titania. With an increase in photoconductivity of titania, the short-circuit current increases accordingly. The increase in open-circuit voltage on extended exposure to air is attributed to an increase in the electrostatic field across the diodes when polythiophene is doped by oxygen.

Original language	English (US)
Article number	113302
Journal	Applied Physics Letters
Volume	94
Issue number	11
DOIs	https://doi.org/10.1063/1.3099947
State	Published - 2009

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Physics and Astronomy (miscellaneous)

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10.1063/1.3099947

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title = "Transient photovoltaic behavior of air-stable, inverted organic solar cells with solution-processed electron transport layer",

abstract = "The short-circuit current density of inverted organic solar cells comprising a solution-processed titania electron transport layer increases with continuous illumination in air and saturates after 10 min. On extended exposure (>2 days), the open-circuit voltage of the devices increases also. The improvement in device characteristics over short time scales is attributed to the filling of shallow electron traps in titania. With an increase in photoconductivity of titania, the short-circuit current increases accordingly. The increase in open-circuit voltage on extended exposure to air is attributed to an increase in the electrostatic field across the diodes when polythiophene is doped by oxygen.",

author = "Kim, \{Chang Su\} and Lee, \{Stephanie S.\} and Gomez, \{Enrique D.\} and Kim, \{Jong Bok\} and Loo, \{Yueh Lin\}",

note = "Funding Information: The National Science Foundation MRSEC Program supported this work through the Princeton Center for Complex Materials (Contract No. DMR-0819860). Copyright: Copyright 2009 Elsevier B.V., All rights reserved.",

year = "2009",

doi = "10.1063/1.3099947",

language = "English (US)",

volume = "94",

journal = "Applied Physics Letters",

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T1 - Transient photovoltaic behavior of air-stable, inverted organic solar cells with solution-processed electron transport layer

AU - Kim, Chang Su

AU - Lee, Stephanie S.

AU - Gomez, Enrique D.

AU - Kim, Jong Bok

AU - Loo, Yueh Lin

N1 - Funding Information: The National Science Foundation MRSEC Program supported this work through the Princeton Center for Complex Materials (Contract No. DMR-0819860). Copyright: Copyright 2009 Elsevier B.V., All rights reserved.

PY - 2009

Y1 - 2009

N2 - The short-circuit current density of inverted organic solar cells comprising a solution-processed titania electron transport layer increases with continuous illumination in air and saturates after 10 min. On extended exposure (>2 days), the open-circuit voltage of the devices increases also. The improvement in device characteristics over short time scales is attributed to the filling of shallow electron traps in titania. With an increase in photoconductivity of titania, the short-circuit current increases accordingly. The increase in open-circuit voltage on extended exposure to air is attributed to an increase in the electrostatic field across the diodes when polythiophene is doped by oxygen.

AB - The short-circuit current density of inverted organic solar cells comprising a solution-processed titania electron transport layer increases with continuous illumination in air and saturates after 10 min. On extended exposure (>2 days), the open-circuit voltage of the devices increases also. The improvement in device characteristics over short time scales is attributed to the filling of shallow electron traps in titania. With an increase in photoconductivity of titania, the short-circuit current increases accordingly. The increase in open-circuit voltage on extended exposure to air is attributed to an increase in the electrostatic field across the diodes when polythiophene is doped by oxygen.

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JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 11

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ER -

Transient photovoltaic behavior of air-stable, inverted organic solar cells with solution-processed electron transport layer

Abstract

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