Multi-Terminal Memtransistors from Polycrystalline Monolayer MoS2

TL;DR

This paper demonstrates the scalable fabrication of multi-terminal MoS2 memtransistors that exhibit gate-tunable synaptic behaviors, enabling complex neuromorphic functions beyond traditional 2-terminal memristors.

Contribution

It introduces a novel multi-terminal MoS2 memtransistor with gate-tunable heterosynaptic functionality and high endurance, advancing neuromorphic device capabilities.

Findings

Gate tunability of 4 orders of magnitude in individual states.

Large switching ratios with high endurance and retention.

Gate-tunable heterosynaptic functionality enabling complex neural simulations.

Abstract

In the last decade, a 2-terminal passive circuit element called a memristor has been developed for non-volatile resistive random access memory and has more recently shown promise for neuromorphic computing. Compared to flash memory, memristors have higher endurance, multi-bit data storage, and faster read/write times. However, although 2-terminal memristors have demonstrated basic neural functions, synapses in the human brain outnumber neurons by more than a factor of 1000, which implies that multiterminal memristors are needed to perform complex functions such as heterosynaptic plasticity. Previous attempts to move beyond 2-terminal memristors include the 3-terminal Widrow-Hoff memistor and field-effect transistors with nanoionic gates or floating gates, albeit without memristive switching in the transistor. Here, we report the scalable experimental realization of a multi-terminal hybrid memristor and transistor (i.e., memtransistor) using polycrystalline monolayer MoS2. Two-dimensional (2D) MoS2 memtransistors show gate tunability in individual states by 4 orders of magnitude in addition to large switching ratios with high cycling endurance and long-term retention of states. In addition to conventional neural learning behavior of long-term potentiation/depression, 6-terminal MoS2 memtransistors possess gate-tunable heterosynaptic functionality that is not achievable using 2-terminal memristors. For example, the conductance between a pair of two floating electrodes (pre-synaptic and post-synaptic neurons) is varied by 10X by applying voltage pulses to modulatory terminals. In situ scanning probe microscopy, cryogenic charge transport measurements, and device modeling reveal that bias-induced MoS2 defect motion drives resistive switching by dynamically varying Schottky barrier heights.