Optimizing the component ratio of PEDOT:PSS by water rinse for high efficiency organic solar cells over 16.7

A new method by water rinse to modify PEDOT:PSS was developed, demonstrating a 16.75% PCE in organic solar cells. [Display omitted] For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suff...

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Published in:Science bulletin Vol. 65; no. 9; pp. 747 - 752
Main Authors: Li, Qicong, Sun, Yang, Yang, Cheng, Liu, Kong, Islam, Md. Rasidul, Li, Long, Wang, Zhijie, Qu, Shengchun
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 15.05.2020
Subjects:
High efficiency
Organic solar cell
PEDOT:PSS
Water rinse
Organic solar cell
High efficiency
Water rinse
PEDOT:PSS
ISSN:2095-9273, 2095-9281, 2095-9281
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Abstract A new method by water rinse to modify PEDOT:PSS was developed, demonstrating a 16.75% PCE in organic solar cells. [Display omitted] For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suffers from several disadvantages, such as low conductivity and harm to ITO due to the acidic PSS. Herein, a simple method is introduced to enhance the conductivity and remove the additional PSS by water rinsing the PEDOT:PSS films. The photovoltaic devices based on the water rinsed PEDOT:PSS present a dramatic improvement in efficiency from 15.98% to 16.75% in comparison to that of the untreated counterparts. Systematic characterization and analysis reveal that although part of the PEDOT:PSS is washed away, it still leaves a smoother film and the ratio of PEDOT to PSS is higher than before in the remaining films. It can greatly improve the conductivity and reduce the damage to substrates. This study demonstrates that finely modifying the charge transport materials to improve conductivity and reduce defeats has great potential for boosting the efficiency of OSCs.
AbstractList For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suffers from several disadvantages, such as low conductivity and harm to ITO due to the acidic PSS. Herein, a simple method is introduced to enhance the conductivity and remove the additional PSS by water rinsing the PEDOT:PSS films. The photovoltaic devices based on the water rinsed PEDOT:PSS present a dramatic improvement in efficiency from 15.98% to 16.75% in comparison to that of the untreated counterparts. Systematic characterization and analysis reveal that although part of the PEDOT:PSS is washed away, it still leaves a smoother film and the ratio of PEDOT to PSS is higher than before in the remaining films. It can greatly improve the conductivity and reduce the damage to substrates. This study demonstrates that finely modifying the charge transport materials to improve conductivity and reduce defeats has great potential for boosting the efficiency of OSCs.
A new method by water rinse to modify PEDOT:PSS was developed, demonstrating a 16.75% PCE in organic solar cells. [Display omitted] For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suffers from several disadvantages, such as low conductivity and harm to ITO due to the acidic PSS. Herein, a simple method is introduced to enhance the conductivity and remove the additional PSS by water rinsing the PEDOT:PSS films. The photovoltaic devices based on the water rinsed PEDOT:PSS present a dramatic improvement in efficiency from 15.98% to 16.75% in comparison to that of the untreated counterparts. Systematic characterization and analysis reveal that although part of the PEDOT:PSS is washed away, it still leaves a smoother film and the ratio of PEDOT to PSS is higher than before in the remaining films. It can greatly improve the conductivity and reduce the damage to substrates. This study demonstrates that finely modifying the charge transport materials to improve conductivity and reduce defeats has great potential for boosting the efficiency of OSCs.
For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suffers from several disadvantages, such as low conductivity and harm to ITO due to the acidic PSS. Herein, a simple method is introduced to enhance the conductivity and remove the additional PSS by water rinsing the PEDOT:PSS films. The photovoltaic devices based on the water rinsed PEDOT:PSS present a dramatic improvement in efficiency from 15.98% to 16.75% in comparison to that of the untreated counterparts. Systematic characterization and analysis reveal that although part of the PEDOT:PSS is washed away, it still leaves a smoother film and the ratio of PEDOT to PSS is higher than before in the remaining films. It can greatly improve the conductivity and reduce the damage to substrates. This study demonstrates that finely modifying the charge transport materials to improve conductivity and reduce defeats has great potential for boosting the efficiency of OSCs.For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it still suffers from several disadvantages, such as low conductivity and harm to ITO due to the acidic PSS. Herein, a simple method is introduced to enhance the conductivity and remove the additional PSS by water rinsing the PEDOT:PSS films. The photovoltaic devices based on the water rinsed PEDOT:PSS present a dramatic improvement in efficiency from 15.98% to 16.75% in comparison to that of the untreated counterparts. Systematic characterization and analysis reveal that although part of the PEDOT:PSS is washed away, it still leaves a smoother film and the ratio of PEDOT to PSS is higher than before in the remaining films. It can greatly improve the conductivity and reduce the damage to substrates. This study demonstrates that finely modifying the charge transport materials to improve conductivity and reduce defeats has great potential for boosting the efficiency of OSCs.
Author Yang, Cheng
Li, Qicong
Sun, Yang
Liu, Kong
Li, Long
Wang, Zhijie
Qu, Shengchun
Islam, Md. Rasidul
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Issue 9
Keywords Organic solar cell
High efficiency
Water rinse
PEDOT:PSS
Language English
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Snippet A new method by water rinse to modify PEDOT:PSS was developed, demonstrating a 16.75% PCE in organic solar cells. [Display omitted] For the state-of-the-art...
For the state-of-the-art organic solar cells (OSCs), PEDOT:PSS is the most popularly used hole transport material for the conventional structure. However, it...
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SubjectTerms High efficiency
Organic solar cell
PEDOT:PSS
Water rinse
Title Optimizing the component ratio of PEDOT:PSS by water rinse for high efficiency organic solar cells over 16.7
URI https://dx.doi.org/10.1016/j.scib.2019.12.021
https://www.ncbi.nlm.nih.gov/pubmed/36659108
https://www.proquest.com/docview/2768238559
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