Díaz-Fernández A, Chico Leonor, González J W, Domínguez-Adame F
GISC, Departamento de Física de Materiales, Universidad Complutense, E-28040, Madrid, Spain.
Department of Physics, University of Warwick, Coventry, CV4 7AL, United Kingdom.
Sci Rep. 2017 Aug 14;7(1):8058. doi: 10.1038/s41598-017-08188-3.
Dirac materials are characterized by energy-momentum relations that resemble those of relativistic massless particles. Commonly denominated Dirac cones, these dispersion relations are considered to be their essential feature. These materials comprise quite diverse examples, such as graphene and topological insulators. Band-engineering techniques should aim to a full control of the parameter that characterizes the Dirac cones: the Fermi velocity. We propose a general mechanism that enables the fine-tuning of the Fermi velocity in Dirac materials in a readily accessible way for experiments. By embedding the sample in a uniform electric field, the Fermi velocity is substantially modified. We first prove this result analytically, for the surface states of a topological insulator/semiconductor interface, and postulate its universality in other Dirac materials. Then we check its correctness in carbon-based Dirac materials, namely graphene nanoribbons and nanotubes, thus showing the validity of our hypothesis in different Dirac systems by means of continuum, tight-binding and ab-initio calculations.
狄拉克材料的特征在于其能量 - 动量关系类似于相对论无质量粒子的关系。这些色散关系通常被称为狄拉克锥,被认为是它们的基本特征。这些材料包含相当多样的例子,如石墨烯和拓扑绝缘体。能带工程技术应旨在完全控制表征狄拉克锥的参数:费米速度。我们提出了一种通用机制,能够以一种实验上易于实现的方式对狄拉克材料中的费米速度进行微调。通过将样品嵌入均匀电场中,费米速度会发生显著改变。我们首先针对拓扑绝缘体/半导体界面的表面态进行了分析证明这一结果,并假定其在其他狄拉克材料中的普遍性。然后我们在碳基狄拉克材料,即石墨烯纳米带和纳米管中验证了其正确性,从而通过连续介质、紧束缚和从头计算表明了我们的假设在不同狄拉克系统中的有效性。
