Ultrathin Ga2O3 Tunneling Contact for 2D Transition-metal Dichalcogenides Transistor

Abstract

The development of two-dimensional (2D) transition metal dichalcogenides (TMDs) based transistors has been constrained by high contact resistance and inadequate current delivery, primarily stemming from metal-induced gap states and Fermi level pinning. Research into addressing these challenges is essential for the advancing 2D transistors from laboratory experiments to industrial-grade production. In this work, we present amorphous Ga2O3 as a novel tunneling contact layer for multilayer WS2-based field-effect transistors (FETs) to enhance electrical performance. The addition of this innovative tunneling layer avoid Schottky barrier forming while finally change into a tunneling barrier with the barrier height to just 3.7 meV, near-ideal ohmic contacts. This approach effectively reduces contact resistance to only 2.38 k\,μm and specific contact resistivity as low as 3 × 10-5 2. A record-high electron mobility of 296 cm2 V-1 s-1 and ON-OFF ratio over 106 are realized for WS2 transistor at room temperature. Compared to other tunneling materials, ultrathin Ga2O3 layer offers scalability, cost-efficient production and broad substrate compatibility, making it well-suited for seamless integration with industrial wafer-scale electronics. A robust device performance remains highly consistent in a large-scale transistor array fabricated on 1.5× 1.5 cm2 chips, with the average mobility closing to 200 cm2 V-1 s-1. These findings establish a new benchmark for contact performance in 2D transistors and prove the potential of tunneling contact engineering in advancing high-performance, scalable 29 pelectronics with promising applications in quantum computing and communication.

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