Topological nonsymmorphic insulator versus Dirac semimetal in KZnBi

IF 2.9 Q3 CHEMISTRY, PHYSICAL
Rahul Verma, Bikash Patra, Bahadur Singh
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Abstract

KZnBi was discovered recently as a new three-dimensional Dirac semimetal with a pair of bulk Dirac fermions in contrast to the Z2 trivial insulator reported earlier. In order to address this discrepancy, we have performed electronic structure and topological state analysis of KZnBi using the local, semilocal, and hybrid exchange-correlation (XC) functionals within the density functional theory framework. We find that various XC functionals, including the SCAN meta-GGA and hybrid functional with 25% Hartree–Fock (HF) exchange (HSE06), resolve a topological nonsymmorphic insulator state with the glide-mirror protected hourglass surface Dirac fermions. By carefully tuning the XC strength in modified Becke-Johnson (mBJ) potential, we recover the correct orbital ordering and Dirac semimetal state of KZnBi. We further show that increasing the default HF exchange in hybrid functional ( > 40%) can also capture the desired Dirac semimetal state with the correct orbital ordering of KZnBi. The calculated energy dispersion and carrier velocities of Dirac states are found to be in excellent agreement with the available experimental results. Our results demonstrate that KZnBi is a unique topological material where large XC effects are crucial to producing the Dirac semimetal state.
KZnBi 中的拓扑非非晶绝缘体与狄拉克半金属
最近发现的 KZnBi 是一种新的三维狄拉克半金属,具有一对体狄拉克费米子,与早先报道的 Z2 三绝缘体截然不同。为了解决这一差异,我们在密度泛函理论框架内使用局部、半局部和混合交换相关(XC)函数对 KZnBi 进行了电子结构和拓扑状态分析。我们发现,各种 XC 函数,包括 SCAN 元-GGA 和含 25% 哈特里-福克(HF)交换的混合函数 (HSE06),解析了具有滑镜保护沙漏表面狄拉克费米子的拓扑非非晶态绝缘体状态。通过仔细调整修正贝克-约翰逊(mBJ)势中的 XC 强度,我们恢复了 KZnBi 的正确轨道排序和狄拉克半金属态。我们进一步证明,增加混合函数中的默认高频交换(40%)也能捕捉到所需的具有正确轨道排序的 KZnBi 的狄拉克半金属态。计算得出的狄拉克态能量弥散和载流子速度与现有的实验结果非常吻合。我们的研究结果表明,KZnBi 是一种独特的拓扑材料,在这种材料中,大 XC 效应是产生狄拉克半金属态的关键。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.70
自引率
11.50%
发文量
46
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