Nanoscale Mapping of the Conductivity and Interfacial Capacitance of an Electrolyte-Gated Organic Field-Effect Transistor under Operation

Adrica Kyndiah; Martí Checa; Francesca Leonardi; Ruben Millan-Solsona; Martina Di Muzio; Shubham Tanwar; Laura Fumagalli; Marta Mas-Torrent; Gabriel Gomila

doi:10.1002/adfm.202008032

Nanoscale Mapping of the Conductivity and Interfacial Capacitance of an Electrolyte-Gated Organic Field-Effect Transistor under Operation

Adrica Kyndiah, Martí Checa, Francesca Leonardi, Ruben Millan-Solsona, Martina Di Muzio, Shubham Tanwar, Laura Fumagalli, Marta Mas-Torrent, Gabriel Gomila

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22 Scopus citations

Abstract

Probing nanoscale electrical properties of organic semiconducting materials at the interface with an electrolyte solution under externally applied voltages is key in the field of organic bioelectronics. It is demonstrated that the conductivity and interfacial capacitance of the active channel of an electrolyte-gated organic field-effect transistor (EGOFET) under operation can be probed at the nanoscale using scanning dielectric microscopy in force detection mode in liquid environment. Local electrostatic force versus gate voltage transfer characteristics are obtained on the device and correlated with the global current–voltage transfer characteristics of the EGOFET. Nanoscale maps of the conductivity of the semiconducting channel show the dependence of the channel conductivity on the gate voltage and its variation along the channel due to the space charge limited conduction. The maps reveal very small electrical heterogeneities, which correspond to local interfacial capacitance variations due to an ultrathin non-uniform insulating layer resulting from a phase separation in the organic semiconducting blend. Present results offer insights into the transduction mechanism at the organic semiconductor/electrolyte interfaces at scales down to ≈100 nm, which can bring substantial optimization of organic electronic devices for bioelectronic applications such as electrical recording on excitable cells or label-free biosensing.

Original language	English
Article number	2008032
Journal	Advanced Functional Materials
Volume	31
Issue number	5
DOIs	https://doi.org/10.1002/adfm.202008032
State	Published - Jan 27 2021
Externally published	Yes

Funding

This work was partially supported by the BEST Postdoctoral Programme funded by the European Commission under Horizon 2020's Marie Curie Sklodowska‐Curie Actions COFUND scheme (GA 712754) and the Severo Ochoa programme of the Spanish Ministry of Science and Competitiveness (SEV‐2014‐0425), the BORGES project (Marie Curie Skłodowska European Training Network (MSCA‐ITN‐ETN)) under the Grant Agreement (GA 813863), and the Agencia Estatal de Investigacion (Nanoelectrophys project, TEC2016‐79156‐P). Support from an ICREA Academia award (G.G.), the 2017‐SGR1079 grant, and the CERCA program from the Generalitat de Catalunya is also acknowledged. F.L. and M.M.‐T. were funded by the Spanish Ministry (project FANCY CTQ2016‐80030‐R and GENESIS PID2019‐111682RB‐I00), the Generalitat de Catalunya (2017‐SGR‐918), and the Spanish Ministry of Economy and Competitiveness, through the “Severo Ochoa” Programme for Centers of Excellence in R&D (SEV‐2015‐0496). F.L. acknowledges the fellowship. L.F. received funding from the European Research Council (grant agreement No. 819417) under the European Union's Horizon 2020 research and innovation programme. The authors would like to thank Prof. T. Cramer for the measurement software of the EGOFETs and for scientific discussion. Juan de la Cierva

Keywords

atomic force microscopy
bioelectronic devices
electrolyte gated organic field effect transistors
in-liquid scanning dielectric microscopy
organic semiconducting blend

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10.1002/adfm.202008032

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title = "Nanoscale Mapping of the Conductivity and Interfacial Capacitance of an Electrolyte-Gated Organic Field-Effect Transistor under Operation",

abstract = "Probing nanoscale electrical properties of organic semiconducting materials at the interface with an electrolyte solution under externally applied voltages is key in the field of organic bioelectronics. It is demonstrated that the conductivity and interfacial capacitance of the active channel of an electrolyte-gated organic field-effect transistor (EGOFET) under operation can be probed at the nanoscale using scanning dielectric microscopy in force detection mode in liquid environment. Local electrostatic force versus gate voltage transfer characteristics are obtained on the device and correlated with the global current–voltage transfer characteristics of the EGOFET. Nanoscale maps of the conductivity of the semiconducting channel show the dependence of the channel conductivity on the gate voltage and its variation along the channel due to the space charge limited conduction. The maps reveal very small electrical heterogeneities, which correspond to local interfacial capacitance variations due to an ultrathin non-uniform insulating layer resulting from a phase separation in the organic semiconducting blend. Present results offer insights into the transduction mechanism at the organic semiconductor/electrolyte interfaces at scales down to ≈100 nm, which can bring substantial optimization of organic electronic devices for bioelectronic applications such as electrical recording on excitable cells or label-free biosensing.",

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AB - Probing nanoscale electrical properties of organic semiconducting materials at the interface with an electrolyte solution under externally applied voltages is key in the field of organic bioelectronics. It is demonstrated that the conductivity and interfacial capacitance of the active channel of an electrolyte-gated organic field-effect transistor (EGOFET) under operation can be probed at the nanoscale using scanning dielectric microscopy in force detection mode in liquid environment. Local electrostatic force versus gate voltage transfer characteristics are obtained on the device and correlated with the global current–voltage transfer characteristics of the EGOFET. Nanoscale maps of the conductivity of the semiconducting channel show the dependence of the channel conductivity on the gate voltage and its variation along the channel due to the space charge limited conduction. The maps reveal very small electrical heterogeneities, which correspond to local interfacial capacitance variations due to an ultrathin non-uniform insulating layer resulting from a phase separation in the organic semiconducting blend. Present results offer insights into the transduction mechanism at the organic semiconductor/electrolyte interfaces at scales down to ≈100 nm, which can bring substantial optimization of organic electronic devices for bioelectronic applications such as electrical recording on excitable cells or label-free biosensing.

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Nanoscale Mapping of the Conductivity and Interfacial Capacitance of an Electrolyte-Gated Organic Field-Effect Transistor under Operation

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