Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands

Guy O.Ngongang Ndjawa; Kenneth R. Graham; Sonya Mollinger; Di M. Wu; David Hanifi; Rohit Prasanna; Bradley D. Rose; Sukumar Dey; Liyang Yu; Jean Luc Brédas; Michael D. McGehee; Alberto Salleo; Aram Amassian

doi:10.1002/aenm.201601995

Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands

Guy O.Ngongang Ndjawa, Kenneth R. Graham, Sonya Mollinger, Di M. Wu, David Hanifi, Rohit Prasanna, Bradley D. Rose, Sukumar Dey, Liyang Yu, Jean Luc Brédas, Michael D. McGehee, Alberto Salleo, Aram Amassian^*

^*Corresponding author for this work

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

39 Scopus citations

Abstract

In organic solar cells (OSCs), the energy of the charge-transfer (CT) complexes at the donor–acceptor interface, E _CT, determines the maximum open-circuit voltage (V _OC). The coexistence of phases with different degrees of order in the donor or the acceptor, as in blends of semi-crystalline donors and fullerenes in bulk heterojunction layers, influences the distribution of CT states and the V _OC enormously. Yet, the question of how structural heterogeneities alter CT states and the V _OC is seldom addressed systematically. In this work, we combine experimental measurements of vacuum-deposited rubrene/C₆₀ bilayer OSCs, with varying microstructure and texture, with density functional theory calculations to determine how relative molecular orientations and extents of structural order influence E _CT and V _OC. We find that varying the microstructure of rubrene gives rise to CT bands with varying energies. The CT band that originates from crystalline rubrene lies up to ≈0.4 eV lower in energy compared to the one that arises from amorphous rubrene. These low-lying CT states contribute strongly to V _OC losses and result mainly from hole delocalization in aggregated rubrene. This work points to the importance of realizing interfacial structural control that prevents the formation of low E _CT configurations and maximizes V _OC.

Original language	English
Journal	Advanced Energy Materials
Volume	7
Issue number	12
DOIs	https://doi.org/10.1002/aenm.201601995
State	Published - 21 Jun 2017
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2017 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim

Keywords

charge-transfer states
open-circuit voltage
organic photovoltaics
semicrystalline donor
small molecule organic solar cells

ASJC Scopus subject areas

Renewable Energy, Sustainability and the Environment
General Materials Science

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1002/aenm.201601995

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Ndjawa, G. O. N., Graham, K. R., Mollinger, S., Wu, D. M., Hanifi, D., Prasanna, R., Rose, B. D., Dey, S., Yu, L., Brédas, J. L., McGehee, M. D., Salleo, A., & Amassian, A. (2017). Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands. Advanced Energy Materials, 7(12). https://doi.org/10.1002/aenm.201601995

@article{f21bc47c5ab047a3b2c8e8e678221626,

title = "Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands",

abstract = "In organic solar cells (OSCs), the energy of the charge-transfer (CT) complexes at the donor–acceptor interface, E CT, determines the maximum open-circuit voltage (V OC). The coexistence of phases with different degrees of order in the donor or the acceptor, as in blends of semi-crystalline donors and fullerenes in bulk heterojunction layers, influences the distribution of CT states and the V OC enormously. Yet, the question of how structural heterogeneities alter CT states and the V OC is seldom addressed systematically. In this work, we combine experimental measurements of vacuum-deposited rubrene/C60 bilayer OSCs, with varying microstructure and texture, with density functional theory calculations to determine how relative molecular orientations and extents of structural order influence E CT and V OC. We find that varying the microstructure of rubrene gives rise to CT bands with varying energies. The CT band that originates from crystalline rubrene lies up to ≈0.4 eV lower in energy compared to the one that arises from amorphous rubrene. These low-lying CT states contribute strongly to V OC losses and result mainly from hole delocalization in aggregated rubrene. This work points to the importance of realizing interfacial structural control that prevents the formation of low E CT configurations and maximizes V OC.",

keywords = "charge-transfer states, open-circuit voltage, organic photovoltaics, semicrystalline donor, small molecule organic solar cells",

author = "Ndjawa, \{Guy O.Ngongang\} and Graham, \{Kenneth R.\} and Sonya Mollinger and Wu, \{Di M.\} and David Hanifi and Rohit Prasanna and Rose, \{Bradley D.\} and Sukumar Dey and Liyang Yu and Br{\'e}das, \{Jean Luc\} and McGehee, \{Michael D.\} and Alberto Salleo and Aram Amassian",

note = "Publisher Copyright: {\textcopyright} 2017 WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2017",

month = jun,

day = "21",

doi = "10.1002/aenm.201601995",

language = "English",

volume = "7",

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Ndjawa, GON, Graham, KR, Mollinger, S, Wu, DM, Hanifi, D, Prasanna, R, Rose, BD, Dey, S, Yu, L, Brédas, JL, McGehee, MD, Salleo, A & Amassian, A 2017, 'Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands', Advanced Energy Materials, vol. 7, no. 12. https://doi.org/10.1002/aenm.201601995

TY - JOUR

T1 - Open-Circuit Voltage in Organic Solar Cells

T2 - The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands

AU - Ndjawa, Guy O.Ngongang

AU - Graham, Kenneth R.

AU - Mollinger, Sonya

AU - Wu, Di M.

AU - Hanifi, David

AU - Prasanna, Rohit

AU - Rose, Bradley D.

AU - Dey, Sukumar

AU - Yu, Liyang

AU - Brédas, Jean Luc

AU - McGehee, Michael D.

AU - Salleo, Alberto

AU - Amassian, Aram

PY - 2017/6/21

Y1 - 2017/6/21

N2 - In organic solar cells (OSCs), the energy of the charge-transfer (CT) complexes at the donor–acceptor interface, E CT, determines the maximum open-circuit voltage (V OC). The coexistence of phases with different degrees of order in the donor or the acceptor, as in blends of semi-crystalline donors and fullerenes in bulk heterojunction layers, influences the distribution of CT states and the V OC enormously. Yet, the question of how structural heterogeneities alter CT states and the V OC is seldom addressed systematically. In this work, we combine experimental measurements of vacuum-deposited rubrene/C60 bilayer OSCs, with varying microstructure and texture, with density functional theory calculations to determine how relative molecular orientations and extents of structural order influence E CT and V OC. We find that varying the microstructure of rubrene gives rise to CT bands with varying energies. The CT band that originates from crystalline rubrene lies up to ≈0.4 eV lower in energy compared to the one that arises from amorphous rubrene. These low-lying CT states contribute strongly to V OC losses and result mainly from hole delocalization in aggregated rubrene. This work points to the importance of realizing interfacial structural control that prevents the formation of low E CT configurations and maximizes V OC.

AB - In organic solar cells (OSCs), the energy of the charge-transfer (CT) complexes at the donor–acceptor interface, E CT, determines the maximum open-circuit voltage (V OC). The coexistence of phases with different degrees of order in the donor or the acceptor, as in blends of semi-crystalline donors and fullerenes in bulk heterojunction layers, influences the distribution of CT states and the V OC enormously. Yet, the question of how structural heterogeneities alter CT states and the V OC is seldom addressed systematically. In this work, we combine experimental measurements of vacuum-deposited rubrene/C60 bilayer OSCs, with varying microstructure and texture, with density functional theory calculations to determine how relative molecular orientations and extents of structural order influence E CT and V OC. We find that varying the microstructure of rubrene gives rise to CT bands with varying energies. The CT band that originates from crystalline rubrene lies up to ≈0.4 eV lower in energy compared to the one that arises from amorphous rubrene. These low-lying CT states contribute strongly to V OC losses and result mainly from hole delocalization in aggregated rubrene. This work points to the importance of realizing interfacial structural control that prevents the formation of low E CT configurations and maximizes V OC.

KW - charge-transfer states

KW - open-circuit voltage

KW - organic photovoltaics

KW - semicrystalline donor

KW - small molecule organic solar cells

UR - https://www.scopus.com/pages/publications/85009926790

U2 - 10.1002/aenm.201601995

DO - 10.1002/aenm.201601995

M3 - Article

AN - SCOPUS:85009926790

SN - 1614-6832

VL - 7

JO - Advanced Energy Materials

JF - Advanced Energy Materials

IS - 12

ER -

Open-Circuit Voltage in Organic Solar Cells: The Impacts of Donor Semicrystallinity and Coexistence of Multiple Interfacial Charge-Transfer Bands

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

UN SDGs

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