A comprehensive understanding of electrochemical and physical phenomena originating the response of electrolyte-gated transistors is crucial for improved handling and design of these devices. However, the lack of suitable tools for direct investigation of microscale effects has hindered the possibility to bridge the gap between experiments and theoretical models. In this contribution, a scanning probe setup is used to explore the operation mechanisms of organic electrochemical transistors by probing the local electrochemical potential of the organic film composing the device channel. Moreover, an interpretative model is developed in order to highlight the meaning of electrochemical doping and to show how the experimental data can give direct access to fundamental device parameters, such as local charge carrier concentration and mobility. This approach is versatile and provides insight into the organic semiconductor/electrolyte interface and useful information for materials characterization, device scaling, and sensing optimization.
Microscopic Determination of Carrier Density and Mobility in Working Organic Electrochemical Transistors / Mariani F.; Conzuelo F.; Cramer T.; Gualandi I.; Possanzini L.; Tessarolo M.; Fraboni B.; Schuhmann W.; Scavetta E.. - In: SMALL. - ISSN 1613-6810. - ELETTRONICO. - 15:42(2019), pp. 1902534.e1902534-1902534.e1902534. [10.1002/smll.201902534]
Microscopic Determination of Carrier Density and Mobility in Working Organic Electrochemical Transistors
Mariani F.;Cramer T.
;Gualandi I.;Possanzini L.;Tessarolo M.;Fraboni B.;Scavetta E.
2019
Abstract
A comprehensive understanding of electrochemical and physical phenomena originating the response of electrolyte-gated transistors is crucial for improved handling and design of these devices. However, the lack of suitable tools for direct investigation of microscale effects has hindered the possibility to bridge the gap between experiments and theoretical models. In this contribution, a scanning probe setup is used to explore the operation mechanisms of organic electrochemical transistors by probing the local electrochemical potential of the organic film composing the device channel. Moreover, an interpretative model is developed in order to highlight the meaning of electrochemical doping and to show how the experimental data can give direct access to fundamental device parameters, such as local charge carrier concentration and mobility. This approach is versatile and provides insight into the organic semiconductor/electrolyte interface and useful information for materials characterization, device scaling, and sensing optimization.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
