Pressure-Driven Metallicity in Ångström-Thickness 2D Bismuth and Layer-Selective Ohmic Contact to MoS<sub>2</sub>
Shuhua Wang, Shibo Fang, Qiang Li, Yunliang Yue, Zongmeng Yang, Xiaotian Sun, Jing Lu, Chit Siong Lau, L. K. Ang, Lain‐Jong Li, Yee Sin Ang
Abstract
Recent fabrication of two-dimensional (2D) metallic bismuth (Bi) via van der Waals (vdW) squeezing offers a route to ultrascaling metal into ångström thickness. However, free-standing 2D Bi is typically semiconducting, which contradicts the experimentally observed metallicity in vdW-squeezed 2D Bi. Here we show that this discrepancy originates from the pressure-induced buckled-to-flat structural transition in 2D Bi, changing the electronic structures from semiconducting to semimetallic. Based on the experimentally fabricated MoS 2 -Bi-MoS 2 trilayer heterostructure, we demonstrate the concept of layer-selective Ohmic contact in which one MoS 2 layer forms an Ohmic contact to the 2D Bi while the opposite MoS 2 exhibits a Schottky barrier. The Ohmic contact can be switched between the two sandwiching MoS 2 monolayers by reversing an external gate field, thus enabling charge to be spatially injected into different MoS 2 layers. The layer-selective Ohmic contact proposed here represents a layertronic generalization of semimetal/semiconductor contact, paving the way toward layertronic device application.