膨胀的
材料科学
纳米技术
铁电性
相(物质)
转化式学习
桥接(联网)
应变工程
分子工程
工程物理
领域(数学)
财产(哲学)
生物电子学
相位控制
有可能
光学(聚焦)
系统工程
纳米制造
灵活性(工程)
作者
Sheng Li,Fuwei Zhuge,Tianyou Zhai
标识
DOI:10.1002/adma.202523698
摘要
The diverse polymorphic phases of 2D materials constitute a unique platform for property engineering, making precise phase control a pivotal enabler for next-generation electronics. This review provides a comprehensive survey of recent advances in the phase engineering of 2D materials, with a focus on metal chalcogenides that exhibit rich polymorphism and stoichiometry-dependent structural variations. We begin by outlining the expansive phase space and corresponding property spectrum, spanning semiconducting, metallic, insulating, and ferroelectric states. We then delve into the fundamental principles and experimental methodologies for precise phase manipulation, including pathways toward phase-pure synthesis and both irreversible and reversible phase transformations, while highlighting the governing roles of thermodynamics, kinetics, and stoichiometry. Furthermore, we showcase how these strategies enable revolutionary device concepts, such as high-performance 2D transistors, phase-change memories, and ferroelectric devices. Finally, we discuss the remaining challenges and future perspectives in achieving scalable integration and dynamic phase control, underscoring the transformative potential of phase engineering in advancing the field of 2D electronics.
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