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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

2025Nano Letters10 citationsDOI

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.

Topics & Concepts

Ohmic contactBismuthMaterials sciencevan der Waals forceCondensed matter physicsMonolayerSchottky diodeOptoelectronicsFabricationTransition metalMetalSchottky barrierNanotechnologyChemical physicsElectrical contactsSemimetalElectronic structureSemiconductorMetallicityContact resistance2D Materials and ApplicationsMXene and MAX Phase MaterialsTopological Materials and Phenomena