Giant Ferroelectric Resistance Switching Controlled by a Modulatory Terminal for Low-Power Neuromorphic In-Memory Computing

Ferroelectrics have been demonstrated as excellent building blocks for high-performance nonvolatile memories, including memristors, which play critical roles in the hardware implementation of artificial synapses and in-memory computing. Here, it is reported that the emerging van der Waals ferroelectric alpha-In2Se3 can be used to successfully implement heterosynaptic plasticity (a fundamental but rarely emulated synaptic form) and achieve a resistance-switching ratio of heterosynaptic memristors above 10(3), which is two orders of magnitude larger than that in other similar devices. The polarization change of ferroelectric alpha-In2Se3 channel is responsible for the resistance switching at various paired terminals. The third terminal of alpha-In2Se3 memristors exhibits nonvolatile control over channel current at a picoampere level, endowing the devices with picojoule read-energy consumption to emulate the associative heterosynaptic learning. The simulation proves that both supervised and unsupervised learning manners can be implemented in alpha-In2Se3 neutral networks with high image recognition accuracy. Moreover, these heterosynaptic devices can naturally realize Boolean logic without an additional circuit component. The results suggest that van der Waals ferroelectrics hold great potential for applications in complex, energy-efficient, brain-inspired computing systems and logic-in-memory computers.

Automated summary

Van der Waals ferroelectric alpha-In2Se3 has demonstrated successful implementation of heterosynaptic plasticity and achieved high resistance switching ratio in memristors for associative heterosynaptic learning. This material has potential applications in energy-efficient computing systems and logic-in-memory computers.