Symmetric Complementary Logic Inverter Using Integrated Black Phosphorus and MoS2 Transistors

TL;DR

This paper reports the development of a symmetric complementary logic inverter using integrated black phosphorus and MoS2 transistors, demonstrating promising electrical characteristics for 2D material-based logic circuits.

Contribution

It introduces a novel 2D material inverter with well-matched input/output voltages and stable operation, advancing practical applications of 2D electronics.

Findings

Voltage gain of 3.5 at VDD=2.5 V

Static noise margin over 500 mV

Operation demonstrated up to 100 kHz frequency

Abstract

The operation of an integrated two-dimensional complementary metal-oxide-semiconductor inverter with well-matched input/output voltages is reported. The circuit combines a few-layer MoS2 n-MOSFET and a black phosphorus (BP) p-MOSFET fabricated using a common local backgate electrode with thin (20 nm) HfO2 gate dielectric. The constituent devices have linear threshold voltages of -0.8 V and +0.8 V and produce peak transconductances of 16 uS/um and 41 uS/um for the MoS2 n-MOSFET and BP p-MOSFET, respectively. The inverter shows a voltage gain of 3.5 at a supply voltage, VDD = 2.5 V, and has peak switching current of 108 uA and off-state current of 8.4 uA (2.4 uA) at VIN = 0 (VIN = 2.5 V). In addition, the inverter has voltage gain greater than unity for VDD > 0.5 V, has open butterfly curves for VDD > 1 V, and achieves static noise margin over 500 mV at VDD = 2.5 V. The voltage gain was found to be insensitive to temperature between 270 K and 340 K, and AC large and small-signal operation was demonstrated at frequencies up to 100 kHz. The demonstration of a complementary 2D inverter which operates in a symmetric voltage window suitable for driving a subsequent logic stage is a significant step forward in developing practical applications for devices based upon 2D materials.