A reconfigurable field-effect transistor based on a hexagonal boron nitride/rhenium diselenide/hexagonal boron nitride heterostructure offers nonvolatile control of polarity through photoinduced trapping mechanism and can emulate synaptic functions.
Reconfigurable field-effect transistors (FETs) combine unipolar n- and p-type characteristics in a single programmable device and could be used to reduce the complexity of electronic devices. However, current reconfigurable FETs require a constant voltage supply to achieve polarity conversion, leading to high power consumption. Here we report a reconfigurable FET that is based on a hexagonal boron nitride/rhenium diselenide/hexagonal boron nitride (hBN/ReSe2/hBN) heterostructure and has a nonvolatile and tunable polarity. A photoinduced trapping mechanism is used to drive photoexcited holes or electrons into the interface between the hBN and the silicon dioxide substrate. The reconfigurable FET can switch between a transistor and memory mode, and several FETs can be used to create inverter, AND, OR, NAND, NOR, XOR and XNOR circuits. We also show that, when in memory-mode operation, the devices can be used to emulate synaptic functions for neuromorphic computing systems. A reconfigurable field-effect transistor based on a hexagonal boron nitride/rhenium diselenide/hexagonal boron nitride heterostructure can offer nonvolatile control of its channel conductivity via photoinduced trapping of electrons or holes at the bottom dielectric interface.
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