Improved organic electrochemical transistor stability using solvent degassing and chemical doping

Vianna N. Le; Kyle N. Baustert; Megan R. Brown; Joel H. Bombile; Lucas Q. Flagg; Karl Thorley; Christina J. Kousseff; Olga Solomeshch; Iain McCulloch; Nir Tessler; Chad Risko; Kenneth R. Graham; Alexandra F. Paterson

doi:10.1038/s41928-024-01297-8

Improved organic electrochemical transistor stability using solvent degassing and chemical doping

Vianna N. Le
, Kyle N. Baustert
, Megan R. Brown
, Joel H. Bombile
, Lucas Q. Flagg
, Karl Thorley
, Christina J. Kousseff
, Olga Solomeshch
, Iain McCulloch
, Nir Tessler
, Chad Risko
, Kenneth R. Graham
, Alexandra F. Paterson

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

7 Scopus citations

Abstract

Organic mixed ionic–electronic conductors (OMIECs), which can be used to build organic electrochemical transistors (OECTs), are of potential use in flexible, large-area and bioelectronic systems. Although hole-transporting p-type OMIECs are susceptible to oxidation, and oxygen leads to OECT instability, it is unclear whether oxygen also behaves as an uncontrolled p-dopant. We show that oxygen dissolved in a solvent can act as a p-dopant in OMIECs and OECTs by filling traps to enable effective electrochemical doping. To address the fact that the presence of oxygen simultaneously jeopardizes OECT stability, we develop a two-step strategy in which we first degas the solvent, and then dope the OMIEC in a controlled manner using a chemical dopant. Our approach improves the stability of both p-type and n-type OECTs, while increasing the on–off ratio, tuning the threshold voltage and enhancing the transconductance, charge carrier mobility, and the µC* product—that is, the product of mobility and the volumetric capacitance.

Original language	English (US)
Article number	1575
Pages (from-to)	116-126
Number of pages	11
Journal	Nature Electronics
Volume	8
Issue number	2
DOIs	https://doi.org/10.1038/s41928-024-01297-8
State	Published - Feb 2025
Externally published	Yes

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
Instrumentation
Electrical and Electronic Engineering

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10.1038/s41928-024-01297-8

Cite this

Le, V. N., Baustert, K. N., Brown, M. R., Bombile, J. H., Flagg, L. Q., Thorley, K., Kousseff, C. J., Solomeshch, O., McCulloch, I., Tessler, N., Risko, C., Graham, K. R., & Paterson, A. F. (2025). Improved organic electrochemical transistor stability using solvent degassing and chemical doping. Nature Electronics, 8(2), 116-126. Article 1575. https://doi.org/10.1038/s41928-024-01297-8

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title = "Improved organic electrochemical transistor stability using solvent degassing and chemical doping",

abstract = "Organic mixed ionic–electronic conductors (OMIECs), which can be used to build organic electrochemical transistors (OECTs), are of potential use in flexible, large-area and bioelectronic systems. Although hole-transporting p-type OMIECs are susceptible to oxidation, and oxygen leads to OECT instability, it is unclear whether oxygen also behaves as an uncontrolled p-dopant. We show that oxygen dissolved in a solvent can act as a p-dopant in OMIECs and OECTs by filling traps to enable effective electrochemical doping. To address the fact that the presence of oxygen simultaneously jeopardizes OECT stability, we develop a two-step strategy in which we first degas the solvent, and then dope the OMIEC in a controlled manner using a chemical dopant. Our approach improves the stability of both p-type and n-type OECTs, while increasing the on–off ratio, tuning the threshold voltage and enhancing the transconductance, charge carrier mobility, and the µC* product—that is, the product of mobility and the volumetric capacitance.",

author = "Le, \{Vianna N.\} and Baustert, \{Kyle N.\} and Brown, \{Megan R.\} and Bombile, \{Joel H.\} and Flagg, \{Lucas Q.\} and Karl Thorley and Kousseff, \{Christina J.\} and Olga Solomeshch and Iain McCulloch and Nir Tessler and Chad Risko and Graham, \{Kenneth R.\} and Paterson, \{Alexandra F.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

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doi = "10.1038/s41928-024-01297-8",

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AU - Thorley, Karl

AU - Kousseff, Christina J.

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AU - McCulloch, Iain

AU - Tessler, Nir

AU - Risko, Chad

AU - Graham, Kenneth R.

AU - Paterson, Alexandra F.

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N2 - Organic mixed ionic–electronic conductors (OMIECs), which can be used to build organic electrochemical transistors (OECTs), are of potential use in flexible, large-area and bioelectronic systems. Although hole-transporting p-type OMIECs are susceptible to oxidation, and oxygen leads to OECT instability, it is unclear whether oxygen also behaves as an uncontrolled p-dopant. We show that oxygen dissolved in a solvent can act as a p-dopant in OMIECs and OECTs by filling traps to enable effective electrochemical doping. To address the fact that the presence of oxygen simultaneously jeopardizes OECT stability, we develop a two-step strategy in which we first degas the solvent, and then dope the OMIEC in a controlled manner using a chemical dopant. Our approach improves the stability of both p-type and n-type OECTs, while increasing the on–off ratio, tuning the threshold voltage and enhancing the transconductance, charge carrier mobility, and the µC* product—that is, the product of mobility and the volumetric capacitance.

AB - Organic mixed ionic–electronic conductors (OMIECs), which can be used to build organic electrochemical transistors (OECTs), are of potential use in flexible, large-area and bioelectronic systems. Although hole-transporting p-type OMIECs are susceptible to oxidation, and oxygen leads to OECT instability, it is unclear whether oxygen also behaves as an uncontrolled p-dopant. We show that oxygen dissolved in a solvent can act as a p-dopant in OMIECs and OECTs by filling traps to enable effective electrochemical doping. To address the fact that the presence of oxygen simultaneously jeopardizes OECT stability, we develop a two-step strategy in which we first degas the solvent, and then dope the OMIEC in a controlled manner using a chemical dopant. Our approach improves the stability of both p-type and n-type OECTs, while increasing the on–off ratio, tuning the threshold voltage and enhancing the transconductance, charge carrier mobility, and the µC* product—that is, the product of mobility and the volumetric capacitance.

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Improved organic electrochemical transistor stability using solvent degassing and chemical doping

Abstract

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