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Gate-Tunable Semiconductor Heterojunctions from 2D/3D van der Waals Interfaces

Jinshui Miao, Xiwen Liu, Kiyoung Jo, Kang He, Ravindra Saxena, Baokun Song, Huiqin Zhang, Jiale He, Myung‐Geun Han, Weida Hu, Deep Jariwala

2020Nano Letters98 citationsDOIOpen Access PDF

Abstract

van der Waals (vdW) semiconductors are attractive for highly scaled devices and heterogeneous integration as they can be isolated into self-passivated, two-dimensional (2D) layers that enable superior electrostatic control. These attributes have led to numerous demonstrations of field-effect devices ranging from transistors to triodes. By exploiting the controlled, substitutional doping schemes in covalently bonded, three-dimensional (3D) semiconductors and the passivated surfaces of 2D semiconductors, one can construct devices that can exceed performance metrics of “all-2D” vdW heterojunctions. Here, we demonstrate 2D/3D semiconductor heterojunctions using MoS2 as the prototypical 2D semiconductor laid upon Si and GaN as the 3D semiconductor layers. By tuning the Fermi levels in MoS2, we demonstrate devices that concurrently exhibit over 7 orders of magnitude modulation in rectification ratios and conductance. Our results further suggest that the interface quality does not necessarily affect Fermi level tuning at the junction, opening up possibilities for novel 2D/3D heterojunction device architectures.

Topics & Concepts

HeterojunctionSemiconductorvan der Waals forceRectificationOptoelectronicsMaterials scienceDopingFermi levelField-effect transistorNanotechnologyTransistorChemistryPhysicsVoltageElectronQuantum mechanicsMoleculeOrganic chemistry2D Materials and ApplicationsGraphene research and applicationsMXene and MAX Phase Materials
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