二维异质结构的I、II、III能带特性综述
A review of Type I, II, and III Energy Band Characteristics of Two-Dimensional Heterostructures
摘要: 自从石墨烯的成功剥离以来,二维材料深受电子科技产品的欢迎。随着技术的进步,单一的二维材料的电子性质已不满足现在的需求。随之而来的是通过各种方法来调控材料的电子性质扩展其应用范围。其中构建异质双层结构是一种有效的方法,它可以保留原有材料的优点,甚至产生新的电子性质。构建的异质双层结构所展现的I、II、III型能带特性使得我们在调控其电子性质时可以选择有效的方法。本文对三种能带特性材料以及其电子性质的调控方法进行了综述。
Abstract: Since graphene was successfully stripped, two-dimensional materials have become increasingly popular in electronic technology products. With the progress of technology, the electronic properties of a single two-dimensional material are not enough to meet the current needs. Among them, the construction of heterogeneous bilayer structure is an effective method, which can retain the advantages of the original material and even present new electronic properties. The type I, II and III energy band characteristics of the constructed heterobilayer structure allow us to choose effective methods to modulate their electronic properties. In this paper, three kinds of energy band characteristic materials and the regulation methods of their electronic properties are reviewed.
文章引用:何文海. 二维异质结构的I、II、III能带特性综述[J]. 物理化学进展, 2024, 13(2): 225-234. https://doi.org/10.12677/japc.2024.132027

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