Synthesis of Large-Sized Van Der Waals Layered MoO Single Crystals with Improved Dielectric Performance

Overview

Journal Precis Chem

Publisher American Chemical Society

Specialty Chemistry

Date 2024 Oct 30

PMID 39474153

Authors

Yaqi Zhu

Beiming Yu

Xin Liu

Jialin Zhang

Zhuofeng Shi

Zhaoning Hu

Saiyu Bu

Chunhu Li

Xiaodong Zhang

Li Lin

Affiliations

Soon will be listed here.

Abstract

The applications of two-dimensional semiconductors strictly require the reliable integration of ultrathin high-κ dielectric materials on the semiconductor surface to enable fine gate control and low power consumption. As layered oxide materials, MoO can be potentially used as a high-κ two-dimensional material with a larger bandgap and high electron affinity. In this work, relying on the oxidization of molybdenum chlorides, we have synthesized α-MoO single crystals, which can be easily exfoliated into flakes with thicknesses of a few nanometers and sizes of hundreds of micrometers and fine thermal stability. Based on measurement results of conventional metal/insulator/metal devices and graphene based dual-gate devices, the as-received MoO nanosheets exhibit improved dielectric performance, including high dielectric constants and competitive breakdown field strength. Our work demonstrates that MoO with improved crystalline quality is a promising candidate for dielectric materials with a large gate capacitance in future electronics based on two-dimensional materials.

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