Ascertaining the limitations of low mobility on organic solar cell performance

B. M. Savoie; S. Tan; J. W. Jerome; C. W. Shu; M. A. Ratner; T. J. Marks

doi:10.1109/IWCE.2012.6242859

Ascertaining the limitations of low mobility on organic solar cell performance

B. M. Savoie^*, S. Tan, J. W. Jerome, C. W. Shu, M. A. Ratner, T. J. Marks

^*Corresponding author for this work

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

2 Scopus citations

Abstract

In the past decade, organic photovoltaics (OPV) have emerged as an intensely studied alternative energy technology. The OPV platform presents several attractive qualities, yet, the high disorder and relative low mobility of the materials comprising OPV systems remain a bottleneck to further progress. We report here a modeling methodology that quantifies the efficiency losses engendered by the low mobility of these systems. We also report a methodology that explicitly treats the charge transfer (CT) state that has been shown to influence device performance. We compare two commonly studied OPV architectures, the bilayer (BL) and blended bulk-heterojunction (BHJ), and separately investigate the sensitivity of each architecture to mobility. Our findings suggest that mismatched mobilities of the active layer components can lead to additional recombination currents. We find that the collection current is largely limited by the slow carrier; consequently, the high mobility carriers only increase the recombination current without aiding collection.

Original language	English (US)
Title of host publication	2012 15th International Workshop on Computational Electronics, IWCE 2012
DOIs	https://doi.org/10.1109/IWCE.2012.6242859
State	Published - Sep 27 2012
Event	2012 15th International Workshop on Computational Electronics, IWCE 2012 - Madison, WI, United States Duration: May 22 2012 → May 25 2012

Other

Other	2012 15th International Workshop on Computational Electronics, IWCE 2012
Country/Territory	United States
City	Madison, WI
Period	5/22/12 → 5/25/12

ASJC Scopus subject areas

Computational Theory and Mathematics
Electrical and Electronic Engineering

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10.1109/IWCE.2012.6242859

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title = "Ascertaining the limitations of low mobility on organic solar cell performance",

abstract = "In the past decade, organic photovoltaics (OPV) have emerged as an intensely studied alternative energy technology. The OPV platform presents several attractive qualities, yet, the high disorder and relative low mobility of the materials comprising OPV systems remain a bottleneck to further progress. We report here a modeling methodology that quantifies the efficiency losses engendered by the low mobility of these systems. We also report a methodology that explicitly treats the charge transfer (CT) state that has been shown to influence device performance. We compare two commonly studied OPV architectures, the bilayer (BL) and blended bulk-heterojunction (BHJ), and separately investigate the sensitivity of each architecture to mobility. Our findings suggest that mismatched mobilities of the active layer components can lead to additional recombination currents. We find that the collection current is largely limited by the slow carrier; consequently, the high mobility carriers only increase the recombination current without aiding collection.",

author = "Savoie, {B. M.} and S. Tan and Jerome, {J. W.} and Shu, {C. W.} and Ratner, {M. A.} and Marks, {T. J.}",

year = "2012",

month = sep,

day = "27",

doi = "10.1109/IWCE.2012.6242859",

language = "English (US)",

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note = "2012 15th International Workshop on Computational Electronics, IWCE 2012 ; Conference date: 22-05-2012 Through 25-05-2012",

}

Savoie, BM, Tan, S, Jerome, JW, Shu, CW, Ratner, MA & Marks, TJ 2012, Ascertaining the limitations of low mobility on organic solar cell performance. in 2012 15th International Workshop on Computational Electronics, IWCE 2012., 6242859, 2012 15th International Workshop on Computational Electronics, IWCE 2012, Madison, WI, United States, 5/22/12. https://doi.org/10.1109/IWCE.2012.6242859

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T1 - Ascertaining the limitations of low mobility on organic solar cell performance

AU - Savoie, B. M.

AU - Tan, S.

AU - Jerome, J. W.

AU - Shu, C. W.

AU - Ratner, M. A.

AU - Marks, T. J.

PY - 2012/9/27

Y1 - 2012/9/27

N2 - In the past decade, organic photovoltaics (OPV) have emerged as an intensely studied alternative energy technology. The OPV platform presents several attractive qualities, yet, the high disorder and relative low mobility of the materials comprising OPV systems remain a bottleneck to further progress. We report here a modeling methodology that quantifies the efficiency losses engendered by the low mobility of these systems. We also report a methodology that explicitly treats the charge transfer (CT) state that has been shown to influence device performance. We compare two commonly studied OPV architectures, the bilayer (BL) and blended bulk-heterojunction (BHJ), and separately investigate the sensitivity of each architecture to mobility. Our findings suggest that mismatched mobilities of the active layer components can lead to additional recombination currents. We find that the collection current is largely limited by the slow carrier; consequently, the high mobility carriers only increase the recombination current without aiding collection.

AB - In the past decade, organic photovoltaics (OPV) have emerged as an intensely studied alternative energy technology. The OPV platform presents several attractive qualities, yet, the high disorder and relative low mobility of the materials comprising OPV systems remain a bottleneck to further progress. We report here a modeling methodology that quantifies the efficiency losses engendered by the low mobility of these systems. We also report a methodology that explicitly treats the charge transfer (CT) state that has been shown to influence device performance. We compare two commonly studied OPV architectures, the bilayer (BL) and blended bulk-heterojunction (BHJ), and separately investigate the sensitivity of each architecture to mobility. Our findings suggest that mismatched mobilities of the active layer components can lead to additional recombination currents. We find that the collection current is largely limited by the slow carrier; consequently, the high mobility carriers only increase the recombination current without aiding collection.

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Y2 - 22 May 2012 through 25 May 2012

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Ascertaining the limitations of low mobility on organic solar cell performance

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