Abstract
Reversibly tunable short-term plasticity (STP) of the channel current in organic neuromorphic devices is demonstrated with a three-terminal architecture. Electrolyte-gated organic transistors—EGOTs...
Highlights
Tunable short-term plasticity (STP) of the channel current in organic neuromorphic devices is demonstrated with a three-terminal architecture
Organic neuromorphic devices were successfully demonstrated toward a wide range of applications,[8] ranging from Pavlovian learning to selective sensing of neurotransmitters,[9] as they can reproduce and make advantage of the two main mechanisms characterizing physiological synapses, namely short-term plasticity STP and long-term potentiation LTP.[10]
This work demonstrates the possibility to exploit the peculiar features of electrolyte-gated organic transistors EGOTs to develop a new class of three-terminal organic neuromorphic devices that exhibit a reversibly tunable short-term plasticity (STP) response of the channel current
Summary
Tunable short-term plasticity (STP) of the channel current in organic neuromorphic devices is demonstrated with a three-terminal architecture. This work demonstrates the possibility to exploit the peculiar features of electrolyte-gated organic transistors EGOTs to develop a new class of three-terminal organic neuromorphic devices that exhibit a reversibly tunable short-term plasticity (STP) response of the channel current.
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