Non-Volatile Reconfigurable Four-Mode van der Waals Transistors and Transformable Logic Circuits

Abstract

Emerging applications in data-intensive computing and circuit security demand logic circuits with high functional density, reconfigurability, and energy efficiency. Here, we demonstrate nonvolatile reconfigurable four-mode field-effect transistors (NVR4M-FETs) based on two-dimensional (2D) MoTe₂ and CuInP₂S₆ (CIPS), offering both polarity switching and threshold voltage modulation. The device exploits the ferroelectric polarization of CIPS at the source/drain regions to achieve dynamic control over the transistor polarity, enabling transitions between n-type and p-type states through polarization-induced local electrostatic doping. Additionally, multilayer graphene floating gates are incorporated to modulate the threshold voltage, yielding four distinct nonvolatile operating modes: n-type logic, p-type logic, always-on memory, and always-off memory. Leveraging the four-mode property, the NVR4M-FET can function as a one-transistor-per-bit ternary content-addressable memory (TCAM). In addition, we demonstrate the construction of transformable logic gates with 14 distinct logic functions using two NVR4M-FETs and a reconfigurable half a dder/subtractor using three NVR4M-FETs integrated with load resistors. Furthermore, we show that a 2-input look-up table can be achieved with eight NVR4M-FETs compared to 12 transistors using reconfigurable transistors, highlighting the potential of NVR4M-FETs for high-density logic circuits. These results underscore the potential of NVR4M-FETs as essential building blocks for energy-efficient, in-memory computing, and secure hardware applications.