The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors

Maryam Alsufyani; Benjamin Moss; Claudia E. Tait; William K. Myers; Maryam Shahi; Katherine Stewart; Xiaolei Zhao; Reem B. Rashid; Dilara Meli; Ruiheng Wu; Bryan D. Paulsen; Karl Thorley; Yuanbao Lin; Craig Combe; Charlie Kniebe-Evans; Sahika Inal; Sang Young Jeong; Han Young Woo; Grant Ritchie; Ji Seon Kim; Jonathan Rivnay; Alexandra Paterson; James R. Durrant; Iain McCulloch

doi:10.1002/adma.202403911

The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors

Maryam Alsufyani, Benjamin Moss, Claudia E. Tait, William K. Myers, Maryam Shahi, Katherine Stewart, Xiaolei Zhao, Reem B. Rashid, Dilara Meli, Ruiheng Wu, Bryan D. Paulsen, Karl Thorley, Yuanbao Lin, Craig Combe, Charlie Kniebe-Evans, Sahika Inal, Sang Young Jeong, Han Young Woo, Grant Ritchie, Ji Seon KimJonathan Rivnay, Alexandra Paterson, James R. Durrant, Iain McCulloch

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

3 Scopus citations

Abstract

A key challenge in the development of organic mixed ionic-electronic conducting materials (OMIEC) for high performance electrochemical transistors is their stable performance in ambient. When operating in aqueous electrolyte, potential reactions of the electrochemically injected electrons with air and water could hinder their persistence, leading to a reduction in charge transport. Here, the impact of deepening the LUMO energy level of a series of electron-transporting semiconducting polymers is evaluated, and subsequently rendering the most common oxidation processes of electron polarons thermodynamically unfavorable, on organic electrochemical transistors (OECTs) performance. Employing time resolved spectroelectrochemistry with three analogous polymers having varying electron affinities (EA), it is found that an EA below the thermodynamic threshold for oxidation of its electron polarons by oxygen significantly improves electron transport and lifetime in air. A polymer with a sufficiently large EA and subsequent thermodynamically unfavorable oxidation of electron polarons is reported, which is used as the semiconducting layer in an OECT, in its neutral and N-DMBI doped form, resulting in an excellent and air-stable OECT performance. These results show a general design methodology to avoid detrimental parasitic reactions under ambient conditions, and the benefits that arise in electrical performance.

Original language	English
Article number	2403911
Journal	Advanced Materials
Volume	36
Issue number	44
DOIs	https://doi.org/10.1002/adma.202403911
State	Published - Nov 1 2024

Bibliographical note

Publisher Copyright:
© 2024 The Author(s). Advanced Materials published by Wiley-VCH GmbH.

Funding

The authors acknowledge financial support from KAUST Office of Sponsored Research CRG10, by EU Horizon2020 grant agreement n\u00B0 952911, BOOSTER, grant agreement n\u00B0862474, RoLA-FLEX, and grant agreement n\u00B0101007084 CITYSOLAR, as well as EPSRC Projects EP/T026219/1, EP/W017091/1, and EP/L011972/1. C.E.T. acknowledges support from the Royal Society through grant URF\u2216R1\u2216201071. For the purpose of Open Access, the author has applied a CC BY public copyright license to any Author Accepted Manuscript (AAM) version arising from this submission. K.S. and J.-S.K. acknowledge the UK EPSRC for funding through both the ATIP Programme Grant (EP/T028513/10) and the Plastic Electronics Centre for Doctoral Training (EP/L016702/1), and the Imperial College High Performance Computing Service for DFT calculations. This work utilized the Keck-II facility of Northwestern University's NUANCE Center and Northwestern University Micro/Nano Fabrication Facility (NUFAB), which are both partially supported by the Soft and Hybrid Nanotechnology Experimental (SHyNE) Resource (NSF ECCS-1542205), the Materials Research Science and Engineering Center (NSF DMR-1720139), the State of Illinois, and Northwestern University. Additionally, the Keck-II facility is partially supported by the International Institute for Nanotechnology (IIN); the Keck Foundation; and the State of Illinois through the II. H.Y.W. acknowledges the financial support from the National Research Foundation of Korea (2019R1A6A1A11044070. This publication is based upon work supported by King Abdullah University of Science and Technology Research Funding (KRF) under Award No. ORA-2021-CRG10-4650. The authors acknowledge financial support from KAUST Office of Sponsored Research CRG10, by EU Horizon2020 grant agreement n\u00B0 952911, BOOSTER, grant agreement n\u00B0862474, RoLA\u2010FLEX, and grant agreement n\u00B0101007084 CITYSOLAR, as well as EPSRC Projects EP/T026219/1, EP/W017091/1, and EP/L011972/1. C.E.T. acknowledges support from the Royal Society through grant URF\u2216R1\u2216201071. For the purpose of Open Access, the author has applied a CC BY public copyright license to any Author Accepted Manuscript (AAM) version arising from this submission. K.S. and J.\u2010S.K. acknowledge the UK EPSRC for funding through both the ATIP Programme Grant (EP/T028513/10) and the Plastic Electronics Centre for Doctoral Training (EP/L016702/1), and the Imperial College High Performance Computing Service for DFT calculations. This work utilized the Keck\u2010II facility of Northwestern University's NUANCE Center and Northwestern University Micro/Nano Fabrication Facility (NUFAB), which are both partially supported by the Soft and Hybrid Nanotechnology Experimental (SHyNE) Resource (NSF ECCS\u20101542205), the Materials Research Science and Engineering Center (NSF DMR\u20101720139), the State of Illinois, and Northwestern University. Additionally, the Keck\u2010II facility is partially supported by the International Institute for Nanotechnology (IIN); the Keck Foundation; and the State of Illinois through the II. H.Y.W. acknowledges the financial support from the National Research Foundation of Korea (2019R1A6A1A11044070. This publication is based upon work supported by King Abdullah University of Science and Technology Research Funding (KRF) under Award No. ORA\u20102021\u2010CRG10\u20104650.

Funders	Funder number
Northwestern Polytechnical University
Imperial College High Performance Computing Service
W. M. Keck Foundation
King Abdullah University of Science and Technology
Northwestern University Micro/Nano Fabrication Facility
King Abdullah University of Science and Technology Research Funding
Illinois State University
Northwestern University Micro/Nano Fabrication Facility
NUFAB
Kortney Rose Foundation	ORA‐2021‐CRG10‐4650
Kortney Rose Foundation
Plastic Electronics Centre for Doctoral Training	EP/L016702/1
Royal Society of Medicine	URF∖R1∖201071, EP/T028513/10
Royal Society of Medicine
Materials Research Science and Engineering Center, Harvard University	DMR‐1720139
Materials Research Science and Engineering Center, Harvard University
EU Horizon2020 Framework	862474, 952911, 101007084
Engineering and Physical Sciences Research Council	EP/L011972/1, EP/W017091/1, EP/T026219/1
Engineering and Physical Sciences Research Council
National Research Foundation of Korea	2019R1A6A1A11044070
National Research Foundation of Korea
Soft and Hybrid Nanotechnology Experimental	NSF ECCS‐1542205
Neurosciences Foundation	ECCS-1542205
Neurosciences Foundation

Keywords

electron affinity
in situ electrochemical resonant Raman spectroscopy
organic electrochemical transistors
semiconducting polymers
time-resolved spectroelectrochemistry

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

Access to Document

10.1002/adma.202403911

Cite this

Alsufyani, M., Moss, B., Tait, C. E., Myers, W. K., Shahi, M., Stewart, K., Zhao, X., Rashid, R. B., Meli, D., Wu, R., Paulsen, B. D., Thorley, K., Lin, Y., Combe, C., Kniebe-Evans, C., Inal, S., Jeong, S. Y., Woo, H. Y., Ritchie, G., ... McCulloch, I. (2024). The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors. Advanced Materials, 36(44), Article 2403911. https://doi.org/10.1002/adma.202403911

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title = "The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors",

abstract = "A key challenge in the development of organic mixed ionic-electronic conducting materials (OMIEC) for high performance electrochemical transistors is their stable performance in ambient. When operating in aqueous electrolyte, potential reactions of the electrochemically injected electrons with air and water could hinder their persistence, leading to a reduction in charge transport. Here, the impact of deepening the LUMO energy level of a series of electron-transporting semiconducting polymers is evaluated, and subsequently rendering the most common oxidation processes of electron polarons thermodynamically unfavorable, on organic electrochemical transistors (OECTs) performance. Employing time resolved spectroelectrochemistry with three analogous polymers having varying electron affinities (EA), it is found that an EA below the thermodynamic threshold for oxidation of its electron polarons by oxygen significantly improves electron transport and lifetime in air. A polymer with a sufficiently large EA and subsequent thermodynamically unfavorable oxidation of electron polarons is reported, which is used as the semiconducting layer in an OECT, in its neutral and N-DMBI doped form, resulting in an excellent and air-stable OECT performance. These results show a general design methodology to avoid detrimental parasitic reactions under ambient conditions, and the benefits that arise in electrical performance.",

keywords = "electron affinity, in situ electrochemical resonant Raman spectroscopy, organic electrochemical transistors, semiconducting polymers, time-resolved spectroelectrochemistry",

author = "Maryam Alsufyani and Benjamin Moss and Tait, \{Claudia E.\} and Myers, \{William K.\} and Maryam Shahi and Katherine Stewart and Xiaolei Zhao and Rashid, \{Reem B.\} and Dilara Meli and Ruiheng Wu and Paulsen, \{Bryan D.\} and Karl Thorley and Yuanbao Lin and Craig Combe and Charlie Kniebe-Evans and Sahika Inal and Jeong, \{Sang Young\} and Woo, \{Han Young\} and Grant Ritchie and Kim, \{Ji Seon\} and Jonathan Rivnay and Alexandra Paterson and Durrant, \{James R.\} and Iain McCulloch",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s). Advanced Materials published by Wiley-VCH GmbH.",

year = "2024",

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Alsufyani, M, Moss, B, Tait, CE, Myers, WK, Shahi, M, Stewart, K, Zhao, X, Rashid, RB, Meli, D, Wu, R, Paulsen, BD, Thorley, K, Lin, Y, Combe, C, Kniebe-Evans, C, Inal, S, Jeong, SY, Woo, HY, Ritchie, G, Kim, JS, Rivnay, J, Paterson, A, Durrant, JR & McCulloch, I 2024, 'The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors', Advanced Materials, vol. 36, no. 44, 2403911. https://doi.org/10.1002/adma.202403911

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T1 - The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors

AU - Alsufyani, Maryam

AU - Moss, Benjamin

AU - Tait, Claudia E.

AU - Myers, William K.

AU - Shahi, Maryam

AU - Stewart, Katherine

AU - Zhao, Xiaolei

AU - Rashid, Reem B.

AU - Meli, Dilara

AU - Wu, Ruiheng

AU - Paulsen, Bryan D.

AU - Thorley, Karl

AU - Lin, Yuanbao

AU - Combe, Craig

AU - Kniebe-Evans, Charlie

AU - Inal, Sahika

AU - Jeong, Sang Young

AU - Woo, Han Young

AU - Ritchie, Grant

AU - Kim, Ji Seon

AU - Rivnay, Jonathan

AU - Paterson, Alexandra

AU - Durrant, James R.

AU - McCulloch, Iain

PY - 2024/11/1

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N2 - A key challenge in the development of organic mixed ionic-electronic conducting materials (OMIEC) for high performance electrochemical transistors is their stable performance in ambient. When operating in aqueous electrolyte, potential reactions of the electrochemically injected electrons with air and water could hinder their persistence, leading to a reduction in charge transport. Here, the impact of deepening the LUMO energy level of a series of electron-transporting semiconducting polymers is evaluated, and subsequently rendering the most common oxidation processes of electron polarons thermodynamically unfavorable, on organic electrochemical transistors (OECTs) performance. Employing time resolved spectroelectrochemistry with three analogous polymers having varying electron affinities (EA), it is found that an EA below the thermodynamic threshold for oxidation of its electron polarons by oxygen significantly improves electron transport and lifetime in air. A polymer with a sufficiently large EA and subsequent thermodynamically unfavorable oxidation of electron polarons is reported, which is used as the semiconducting layer in an OECT, in its neutral and N-DMBI doped form, resulting in an excellent and air-stable OECT performance. These results show a general design methodology to avoid detrimental parasitic reactions under ambient conditions, and the benefits that arise in electrical performance.

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KW - in situ electrochemical resonant Raman spectroscopy

KW - organic electrochemical transistors

KW - semiconducting polymers

KW - time-resolved spectroelectrochemistry

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The Effect of Organic Semiconductor Electron Affinity on Preventing Parasitic Oxidation Reactions Limiting Performance of n-Type Organic Electrochemical Transistors

Abstract

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Funding

Keywords

ASJC Scopus subject areas

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