Enhancing efficiency with fluorinated interlayers in small molecule organic solar cells

Hsieh Cheng Han; Chi Ang Tseng; Chan Yi Du; Abhijit Ganguly; Cheong Wei Chong; Sheng Bo Wang; Chi Feng Lin; Sheng Hsiung Chang; Chao Chin Su; Jiun Haw Lee; Kuei Hsien Chen; Li Chyong Chen

doi:10.1039/c2jm34091g

Enhancing efficiency with fluorinated interlayers in small molecule organic solar cells

Hsieh Cheng Han
, Chi Ang Tseng
, Chan Yi Du
, Abhijit Ganguly
, Cheong Wei Chong
, Sheng Bo Wang
, Chi Feng Lin
, Sheng Hsiung Chang
, Chao Chin Su
, Jiun Haw Lee
, Kuei Hsien Chen
, Li Chyong Chen^*

^*Corresponding author for this work

National Taiwan University
National Central University
Academia Sinica - Institute of Atomic and Molecular Sciences
National Taipei University of Technology

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

23 Scopus citations

Abstract

This study presents a simple approach to improve the performance of small molecule based organic solar cells (OSCs) by inserting a fluorinated buffer layer (e.g., PFAS) at the hetero-interface of bilayer devices. As demonstrated in this work, the PFAS modification reduces the surface energy of the conventional PEDOT:PSS photoanode and results in a significant improvement in the pentacene based OSC. The passivated PEDOT:PSS surface after PFAS modification has a lower interface energy with pentacene and facilitates 3D single crystalline (dendritic-like) phase pentacene growth. Concurrently, the accumulated negative charges of the fluorinated PFAS layer result in the development of interfacial dipole moments that in turn lead to an enhanced built-in potential across the devices, and consequently enhanced hole transport efficiency. Improved performance of the modified OSCs is evident from the ∼97% enhancement in efficiency from 0.88% to 1.73%, along with the open-circuit voltage improvement from 0.29 to 0.42 V. As well as improving the photovoltaic performance, the PFAS treatment also enhances the stability of the device under high temperature annealing, which is essential in the fabrication process.

Original language	English
Pages (from-to)	22899-22905
Number of pages	7
Journal	Journal of Materials Chemistry
Volume	22
Issue number	43
DOIs	https://doi.org/10.1039/c2jm34091g
State	Published - 21 11 2012
Externally published	Yes

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10.1039/c2jm34091g

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@article{3d287ba823a24ab0a81ac8406939a8e1,

title = "Enhancing efficiency with fluorinated interlayers in small molecule organic solar cells",

abstract = "This study presents a simple approach to improve the performance of small molecule based organic solar cells (OSCs) by inserting a fluorinated buffer layer (e.g., PFAS) at the hetero-interface of bilayer devices. As demonstrated in this work, the PFAS modification reduces the surface energy of the conventional PEDOT:PSS photoanode and results in a significant improvement in the pentacene based OSC. The passivated PEDOT:PSS surface after PFAS modification has a lower interface energy with pentacene and facilitates 3D single crystalline (dendritic-like) phase pentacene growth. Concurrently, the accumulated negative charges of the fluorinated PFAS layer result in the development of interfacial dipole moments that in turn lead to an enhanced built-in potential across the devices, and consequently enhanced hole transport efficiency. Improved performance of the modified OSCs is evident from the ∼97\% enhancement in efficiency from 0.88\% to 1.73\%, along with the open-circuit voltage improvement from 0.29 to 0.42 V. As well as improving the photovoltaic performance, the PFAS treatment also enhances the stability of the device under high temperature annealing, which is essential in the fabrication process.",

author = "Han, \{Hsieh Cheng\} and Tseng, \{Chi Ang\} and Du, \{Chan Yi\} and Abhijit Ganguly and Chong, \{Cheong Wei\} and Wang, \{Sheng Bo\} and Lin, \{Chi Feng\} and Chang, \{Sheng Hsiung\} and Su, \{Chao Chin\} and Lee, \{Jiun Haw\} and Chen, \{Kuei Hsien\} and Chen, \{Li Chyong\}",

year = "2012",

month = nov,

day = "21",

doi = "10.1039/c2jm34091g",

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T1 - Enhancing efficiency with fluorinated interlayers in small molecule organic solar cells

AU - Han, Hsieh Cheng

AU - Tseng, Chi Ang

AU - Du, Chan Yi

AU - Ganguly, Abhijit

AU - Chong, Cheong Wei

AU - Wang, Sheng Bo

AU - Lin, Chi Feng

AU - Chang, Sheng Hsiung

AU - Su, Chao Chin

AU - Lee, Jiun Haw

AU - Chen, Kuei Hsien

AU - Chen, Li Chyong

PY - 2012/11/21

Y1 - 2012/11/21

N2 - This study presents a simple approach to improve the performance of small molecule based organic solar cells (OSCs) by inserting a fluorinated buffer layer (e.g., PFAS) at the hetero-interface of bilayer devices. As demonstrated in this work, the PFAS modification reduces the surface energy of the conventional PEDOT:PSS photoanode and results in a significant improvement in the pentacene based OSC. The passivated PEDOT:PSS surface after PFAS modification has a lower interface energy with pentacene and facilitates 3D single crystalline (dendritic-like) phase pentacene growth. Concurrently, the accumulated negative charges of the fluorinated PFAS layer result in the development of interfacial dipole moments that in turn lead to an enhanced built-in potential across the devices, and consequently enhanced hole transport efficiency. Improved performance of the modified OSCs is evident from the ∼97% enhancement in efficiency from 0.88% to 1.73%, along with the open-circuit voltage improvement from 0.29 to 0.42 V. As well as improving the photovoltaic performance, the PFAS treatment also enhances the stability of the device under high temperature annealing, which is essential in the fabrication process.

AB - This study presents a simple approach to improve the performance of small molecule based organic solar cells (OSCs) by inserting a fluorinated buffer layer (e.g., PFAS) at the hetero-interface of bilayer devices. As demonstrated in this work, the PFAS modification reduces the surface energy of the conventional PEDOT:PSS photoanode and results in a significant improvement in the pentacene based OSC. The passivated PEDOT:PSS surface after PFAS modification has a lower interface energy with pentacene and facilitates 3D single crystalline (dendritic-like) phase pentacene growth. Concurrently, the accumulated negative charges of the fluorinated PFAS layer result in the development of interfacial dipole moments that in turn lead to an enhanced built-in potential across the devices, and consequently enhanced hole transport efficiency. Improved performance of the modified OSCs is evident from the ∼97% enhancement in efficiency from 0.88% to 1.73%, along with the open-circuit voltage improvement from 0.29 to 0.42 V. As well as improving the photovoltaic performance, the PFAS treatment also enhances the stability of the device under high temperature annealing, which is essential in the fabrication process.

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DO - 10.1039/c2jm34091g

M3 - 文章

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SN - 0959-9428

VL - 22

SP - 22899

EP - 22905

JO - Journal of Materials Chemistry

JF - Journal of Materials Chemistry

IS - 43

ER -

Enhancing efficiency with fluorinated interlayers in small molecule organic solar cells

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