A Quasi-Solid State DSSC with 10.1% Efficiency through Molecular Design of the Charge-Separation and -Transport

Michio Suzuka; Naoki Hayashi; Takashi Sekiguchi; Kouichi Sumioka; Masakazu Takata; Noriko Hayo; Hiroki Ikeda; Kenichi Oyaizu; Hiroyuki Nishide

doi:10.1038/srep28022

A Quasi-Solid State DSSC with 10.1% Efficiency through Molecular Design of the Charge-Separation and -Transport

Michio Suzuka, Naoki Hayashi, Takashi Sekiguchi, Kouichi Sumioka, Masakazu Takata, Noriko Hayo, Hiroki Ikeda, Kenichi Oyaizu, Hiroyuki Nishide^*

^*Corresponding author for this work

School of Advanced Science and Engineering

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

67 Citations (Scopus)

Abstract

Organic-based solar cells potentially offer a photovoltaic module with low production costs and low hazard risk of the components. We report organic dye-sensitized solar cells, fabricated with molecular designed indoline dyes in conjunction with highly reactive but robust nitroxide radical molecules as redox mediator in a quasi-solid gel form of the electrolyte. The cells achieve conversion efficiencies of 10.1% at 1 sun, and maintain the output performance even under interior lighting. The indoline dyes, customized by introducing long alkyl chains, specifically interact with the radical mediator to suppress a charge-recombination process at the dye interface. The radical mediator also facilitates the charge-transport with remarkably high electron self-exchange rate even in the quasi-solid state electrolyte to lead to a high fill factor.

Original language	English
Article number	28022
Journal	Scientific reports
Volume	6
DOIs	https://doi.org/10.1038/srep28022
Publication status	Published - 2016 Jun 17

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title = "A Quasi-Solid State DSSC with 10.1% Efficiency through Molecular Design of the Charge-Separation and -Transport",

abstract = "Organic-based solar cells potentially offer a photovoltaic module with low production costs and low hazard risk of the components. We report organic dye-sensitized solar cells, fabricated with molecular designed indoline dyes in conjunction with highly reactive but robust nitroxide radical molecules as redox mediator in a quasi-solid gel form of the electrolyte. The cells achieve conversion efficiencies of 10.1% at 1 sun, and maintain the output performance even under interior lighting. The indoline dyes, customized by introducing long alkyl chains, specifically interact with the radical mediator to suppress a charge-recombination process at the dye interface. The radical mediator also facilitates the charge-transport with remarkably high electron self-exchange rate even in the quasi-solid state electrolyte to lead to a high fill factor.",

author = "Michio Suzuka and Naoki Hayashi and Takashi Sekiguchi and Kouichi Sumioka and Masakazu Takata and Noriko Hayo and Hiroki Ikeda and Kenichi Oyaizu and Hiroyuki Nishide",

note = "Funding Information: This work was partially supported by a Research Project on Next-Generation Solar Cell Technology Grant (No. P07015) from NEDO, Japan, and a Grant-in-Aid for Scientific Research (No. 24225003) from MEXT, Japan.",

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doi = "10.1038/srep28022",

language = "English",

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T1 - A Quasi-Solid State DSSC with 10.1% Efficiency through Molecular Design of the Charge-Separation and -Transport

AU - Suzuka, Michio

AU - Hayashi, Naoki

AU - Sekiguchi, Takashi

AU - Sumioka, Kouichi

AU - Takata, Masakazu

AU - Hayo, Noriko

AU - Ikeda, Hiroki

AU - Oyaizu, Kenichi

AU - Nishide, Hiroyuki

N1 - Funding Information: This work was partially supported by a Research Project on Next-Generation Solar Cell Technology Grant (No. P07015) from NEDO, Japan, and a Grant-in-Aid for Scientific Research (No. 24225003) from MEXT, Japan.

PY - 2016/6/17

Y1 - 2016/6/17

N2 - Organic-based solar cells potentially offer a photovoltaic module with low production costs and low hazard risk of the components. We report organic dye-sensitized solar cells, fabricated with molecular designed indoline dyes in conjunction with highly reactive but robust nitroxide radical molecules as redox mediator in a quasi-solid gel form of the electrolyte. The cells achieve conversion efficiencies of 10.1% at 1 sun, and maintain the output performance even under interior lighting. The indoline dyes, customized by introducing long alkyl chains, specifically interact with the radical mediator to suppress a charge-recombination process at the dye interface. The radical mediator also facilitates the charge-transport with remarkably high electron self-exchange rate even in the quasi-solid state electrolyte to lead to a high fill factor.

AB - Organic-based solar cells potentially offer a photovoltaic module with low production costs and low hazard risk of the components. We report organic dye-sensitized solar cells, fabricated with molecular designed indoline dyes in conjunction with highly reactive but robust nitroxide radical molecules as redox mediator in a quasi-solid gel form of the electrolyte. The cells achieve conversion efficiencies of 10.1% at 1 sun, and maintain the output performance even under interior lighting. The indoline dyes, customized by introducing long alkyl chains, specifically interact with the radical mediator to suppress a charge-recombination process at the dye interface. The radical mediator also facilitates the charge-transport with remarkably high electron self-exchange rate even in the quasi-solid state electrolyte to lead to a high fill factor.

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A Quasi-Solid State DSSC with 10.1% Efficiency through Molecular Design of the Charge-Separation and -Transport

Abstract

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