2021
DOI: 10.1021/acsami.1c05938
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Interplay between Electrolyte-Gated Organic Field-Effect Transistors and Surfactants: A Surface Aggregation Tool and Protecting Semiconducting Layer

Abstract: Molecular surfactants, which are based on a water-insoluble tail and a water-soluble head, are widely employed in many areas, such as surface coatings or for drug delivery, thanks to their capability to form micelles in solution or supramolecular structures at the solid/liquid interface. Electrolyte-gated organic field-effect transistors (EGOFETs) are highly sensitive to changes occurring at their electrolyte/gate electrode and electrolyte/organic semiconductor interfaces, and hence, they have been much explor… Show more

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Cited by 9 publications
(9 citation statements)
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“…This may be ascribed to the intercalation of water molecules in the polymer film after prolonged exposure to the aqueous electrolyte, with a consequent decrease of the hole mobility. [31,32] For P3CPT, the analysis confirmed the detrimental effect of the EBS over the polymer behavior. In particular, the absolute value of the V T continuously increased because of the bias stress, which consequently made the transistor always more difficult to switch-on for the same applied gate voltage (Figure 8c).…”
Section: Bias Stress: Continuous Modementioning
confidence: 79%
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“…This may be ascribed to the intercalation of water molecules in the polymer film after prolonged exposure to the aqueous electrolyte, with a consequent decrease of the hole mobility. [31,32] For P3CPT, the analysis confirmed the detrimental effect of the EBS over the polymer behavior. In particular, the absolute value of the V T continuously increased because of the bias stress, which consequently made the transistor always more difficult to switch-on for the same applied gate voltage (Figure 8c).…”
Section: Bias Stress: Continuous Modementioning
confidence: 79%
“…This may be ascribed to the intercalation of water molecules in the polymer film after prolonged exposure to the aqueous electrolyte, with a consequent decrease of the hole mobility. [ 31,32 ]…”
Section: Resultsmentioning
confidence: 99%
“…This trend, an increase of I DS over bias stressing, has been observed in an EGOFET in which the OSC was protected by SAM of cationic/anionic molecules. [ 29 ] Such bias stress instability could originate from charge detrapping from the OSC and polarisation or ion drift in the EDL. It should be emphasized that the current retention during 1h continuous operation observed in the developed device is significantly higher than that of previously reported EGOFETs (≈96% vs 60% to ≈90%) despite the flow of the electrolyte and the higher gate bias ( V GS = –1.2 V).…”
Section: Resultsmentioning
confidence: 99%
“…It should be emphasized that the current retention during 1h continuous operation observed in the developed device is significantly higher than that of previously reported EGOFETs (≈96% vs 60% to ≈90%) despite the flow of the electrolyte and the higher gate bias (V GS = -1.2 V). [30,29] The improved operational stability may come from the more ordered morphology and the interdigitation of the alkyl side chains reducing water diffusion and ion doping. [18] Similarly, the initial I GS rapidly decreased to reach 96% of its minimum value after 100 s (lower panel of the inset of Figure 3a).…”
Section: Device Performance Uniformity and Long-term Operational Stab...mentioning
confidence: 99%
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