Small optical gap molecules and polymers: Using theory to design more efficient materials for organic photovoltaics

Chad Risko; Jean Luc Brédas

doi:10.1007/128-2013-459

Small optical gap molecules and polymers: Using theory to design more efficient materials for organic photovoltaics

Chad Risko, Jean Luc Brédas

Research output: Chapter in Book/Report/Conference proceeding › Chapter

19 Scopus citations

Abstract

Recent improvements in the power conversion efficiencies of organic solar cells have been derived through a combination of new materials, processing, and device designs. A key factor has also been quantum-chemical studies that have led to a better understanding not only of the intrinsic electronic and optical properties of the materials but also of the physical processes that take place during the photovoltaic effect. In this chapter we review some recent quantum-chemical investigations of donor-acceptor copolymers, systems that have found wide use as the primary absorbing and hole-transport materials in bulk-heterojunction solar cells. We underline a number of current limitations with regard to available electronic structure methods and in terms of the understanding of the processes involved in solar cell operation. We conclude with a brief outlook that discusses the need to develop multiscale simulation methods that combine quantum-chemical techniques with large-scale classically-based simulations to provide a more complete picture.

Original language	English (US)
Title of host publication	Multiscale Modelling of Organic and Hybrid Photovoltaics
Publisher	Springer-Verlag
Pages	1-38
Number of pages	38
ISBN (Print)	9783662438732
DOIs	https://doi.org/10.1007/128-2013-459
State	Published - 2014
Externally published	Yes

Publication series

Name	Topics in Current Chemistry
Volume	352
ISSN (Print)	0340-1022

Keywords

Donor-acceptor copolymers
Electronic structure methods
Organic solar cells

ASJC Scopus subject areas

General Chemistry

Access to Document

10.1007/128-2013-459

Cite this

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title = "Small optical gap molecules and polymers: Using theory to design more efficient materials for organic photovoltaics",

abstract = "Recent improvements in the power conversion efficiencies of organic solar cells have been derived through a combination of new materials, processing, and device designs. A key factor has also been quantum-chemical studies that have led to a better understanding not only of the intrinsic electronic and optical properties of the materials but also of the physical processes that take place during the photovoltaic effect. In this chapter we review some recent quantum-chemical investigations of donor-acceptor copolymers, systems that have found wide use as the primary absorbing and hole-transport materials in bulk-heterojunction solar cells. We underline a number of current limitations with regard to available electronic structure methods and in terms of the understanding of the processes involved in solar cell operation. We conclude with a brief outlook that discusses the need to develop multiscale simulation methods that combine quantum-chemical techniques with large-scale classically-based simulations to provide a more complete picture.",

keywords = "Donor-acceptor copolymers, Electronic structure methods, Organic solar cells",

author = "Chad Risko and Br{\'e}das, {Jean Luc}",

note = "Funding Information: This work was funded by the Office of Naval Research (Award No. N00014-11-1-0211) and by the Deanship of Scientific Research (DSR) of King Abdulaziz University (Award No. 23-3-1432/HiCi), which the authors acknowledge for technical and financial support. We are also greatly indebted to our many colleagues that have contributed to the work in organic photovoltaics reviewed herein, including Zhenan Bao, Pierre M. Beaujuge, David Beljonne, J{\'e}r{\^o}me Cornil, Veaceslav Coropceanu, Bernard Kippelen, Hong Li, Seth R. Marder, Michael D. McGehee, Joseph E. Norton, Laxman Pandey, John R. Reynolds, Alberto Salleo, John S. Sears, and Yuanping Yi. ",

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Y1 - 2014

N2 - Recent improvements in the power conversion efficiencies of organic solar cells have been derived through a combination of new materials, processing, and device designs. A key factor has also been quantum-chemical studies that have led to a better understanding not only of the intrinsic electronic and optical properties of the materials but also of the physical processes that take place during the photovoltaic effect. In this chapter we review some recent quantum-chemical investigations of donor-acceptor copolymers, systems that have found wide use as the primary absorbing and hole-transport materials in bulk-heterojunction solar cells. We underline a number of current limitations with regard to available electronic structure methods and in terms of the understanding of the processes involved in solar cell operation. We conclude with a brief outlook that discusses the need to develop multiscale simulation methods that combine quantum-chemical techniques with large-scale classically-based simulations to provide a more complete picture.

AB - Recent improvements in the power conversion efficiencies of organic solar cells have been derived through a combination of new materials, processing, and device designs. A key factor has also been quantum-chemical studies that have led to a better understanding not only of the intrinsic electronic and optical properties of the materials but also of the physical processes that take place during the photovoltaic effect. In this chapter we review some recent quantum-chemical investigations of donor-acceptor copolymers, systems that have found wide use as the primary absorbing and hole-transport materials in bulk-heterojunction solar cells. We underline a number of current limitations with regard to available electronic structure methods and in terms of the understanding of the processes involved in solar cell operation. We conclude with a brief outlook that discusses the need to develop multiscale simulation methods that combine quantum-chemical techniques with large-scale classically-based simulations to provide a more complete picture.

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Small optical gap molecules and polymers: Using theory to design more efficient materials for organic photovoltaics

Abstract

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Keywords

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