posted on 2021-04-13, 18:03authored byQihan Liu, Chun Zhao, Tianshi Zhao, Yina Liu, Ivona Z. Mitrovic, Wangying Xu, Li Yang, Ce Zhou Zhao
The
ecofriendly combustion synthesis (ECS) and self-combustion
synthesis (ESCS) have been successfully utilized to deposit high-k aluminum oxide (AlOx) dielectrics
at low temperatures and applied for aqueous In2O3 thin-film transistors (TFTs) accordingly. The ECS and ESCS processes
facilitate the formation of high-quality dielectrics at lower temperatures
compared to conventional methods based on an ethanol precursor, as
confirmed by thermal analysis and chemical composition characterization.
The aqueous In2O3 TFTs based on ECS and ESCS-AlOx show enhanced electrical characteristics and
counterclockwise transfer-curve hysteresis. The memory-like counterclockwise
behavior in the transfer curve modulated by the gate bias voltage
is comparable to the signal modulation by the neurotransmitters. ECS
and ESCS transistors are employed to perform synaptic emulation; various
short-term and long-term memory functions are emulated with low operating
voltages and high excitatory postsynaptic current levels. High stability
and reproducibility are achieved within 240 pulses of long-term synaptic
potentiation and depression. The synaptic emulation functions achieved
in this work match the demand for artificial neural networks (ANN),
and a multilayer perceptron (MLP) is developed using an ECS-AlOx synaptic transistor for image recognition.
A superior recognition rate of over 90% is achieved based on ECS-AlOx synaptic transistors, which facilitates the
implementation of the metal-oxide synaptic transistor for future neuromorphic
computing via an ecofriendly route.