%AYao, Yao%AHuang, Wei%AChen, Jianhua%AWang, Gang%AChen, Hongming%AZhuang, Xinming%AYing, Yibin%APing, Jianfeng%AMarks, Tobin%AFacchetti, Antonio%BJournal Name: Proceedings of the National Academy of Sciences; Journal Volume: 118; Journal Issue: 44; Related Information: CHORUS Timestamp: 2021-11-12 10:20:49 %D2021%IProceedings of the National Academy of Sciences; None %JJournal Name: Proceedings of the National Academy of Sciences; Journal Volume: 118; Journal Issue: 44; Related Information: CHORUS Timestamp: 2021-11-12 10:20:49 %K %MOSTI ID: 10306442 %PMedium: X %TFlexible complementary circuits operating at sub-0.5 V via hybrid organic–inorganic electrolyte-gated transistors %X

Electrolyte-gated transistors (EGTs) hold great promise for next-generation printed logic circuitry, biocompatible integrated sensors, and neuromorphic devices. However, EGT-based complementary circuits with high voltage gain and ultralow driving voltage (<0.5 V) are currently unrealized, because achieving balanced electrical output for both the p- and n-type EGT components has not been possible with current materials. Here we report high-performance EGT complementary circuits containing p-type organic electrochemical transistors (OECTs) fabricated with an ion-permeable organic semiconducting polymer (DPP-g2T) and an n-type electrical double-layer transistor (EDLT) fabricated with an ion-impermeable inorganic indium–gallium–zinc oxide (IGZO) semiconductor. Adjusting the IGZO composition enables tunable EDLT output which, for In:Ga:Zn = 10:1:1 at%, balances that of the DPP-g2T OECT. The resulting hybrid electrolyte-gated inverter (HCIN) achieves ultrahigh voltage gains (>110) under a supply voltage of only 0.7 V. Furthermore, NAND and NOR logic circuits on both rigid and flexible substrates are realized, enabling not only excellent logic response with driving voltages as low as 0.2 V but also impressive mechanical flexibility down to 1-mm bending radii. Finally, the HCIN was applied in electrooculographic (EOG) signal monitoring for recording eye movement, which is critical for the development of wearable medical sensors and also interfaces for human–computer interaction; the high voltage amplification of the present HCIN enables EOG signal amplification and monitoring in which a small ∼1.5 mV signal is amplified to ∼30 mV.

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