Semi-Dirac semimetal in silicene oxide

In recent years, topological semimetals/metals, including nodal point, nodal line, and nodal surface semimetals/metals, have been studied extensively because of their potential applications in spintronics and quantum computers. In this study, we predict a family of materials, Zr 3 X (X = Al, Ga, In), hosting the nodal loop and nodal surface states in the absence of spin-orbit coupling. Remarkably, the energy variation of the nodal loop and nodal surface states in Zr 3 X are very small, and these topological signatures lie very close to the Fermi level. When the effect of spin-orbit coupling is considered, the nodal loop and nodal surface states exhibit small energy gaps (<25 and 35 meV, respectively) that are suitable observables that reflect the spin-orbit coupling response of these topological signatures and can be detected in experiments. Moreover, these compounds are dynamically stable, and they consequently form potential material platforms to study nodal loop and nodal surface semimetals.

Section: Introductionmentioning

confidence: 99%

Hexagonal Zr3X (X = Al, Ga, In) Metals: High Dynamic Stability, Nodal Loop, and Perfect Nodal Surface States

Gao

2020

“…After a long time of study on 2D materials, it was found that 2D material has extensive applications and is considered to be one of the most attractive and interesting material fields. All 2D materials show outstanding properties (Vahedi Fakhrabad et al, 2015;Xu et al, 2016;Zhong et al, 2017;Yuan et al, 2018;Luo et al, 2021), for example, the transition metal dichalcogenides (TMDs) materials have remarkable mechanical (Liu and Li, 2015), electronic (Zhang and Singh, 2009), optical (He et al, 2014), magnetic (Yuan et al, 2020) and thermal stability (Ding et al, 2016). Phosphorous possesses novel physical, chemical, optical properties and electrical conductivity (Li and Chen, 2014;Lee et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Band Bending Mechanism in CdO/Arsenene Heterostructure: A Potential Direct Z-scheme Photocatalyst

Ren

Zheng

et al. 2021

For the few years, two-dimensional (2D) materials have aroused general focus. In order to expand the properties and application range of 2D materials, two different layered materials are usually combined into heterostructure through van der Waals (vdW) interaction. In this research, based on first-principles simulation, we propose CdO/Arsenene (CdO/As) vdW heterostructure as a semiconductor possessing a direct bandgap by 2.179 eV. Besides, the CdO/As vdW heterostructure presents type-II band alignment, which can be used as a remarkable photocatalyst. Importantly, the CdO/As heterostructure demonstrates a direct Z-type principle photocatalyst by exploring the band bending mechanism in the heterostructure. Furthermore, we calculated the light absorption characteristics of CdO/As vdW heterostructure by optical absorption spectrum and conversion efficiency of a novel solar-to-hydrogen efficiency (ηSTH) about 11.67%, which is much higher than that of other 2D photocatalysts. Our work can provide a theoretical guidance for the designing of Z-scheme photocatalyst.

“…After the discovery of topological insulators (Zhang et al, 2009 ; Hasan and Kane, 2010 ; Yu et al, 2010 ; Qi and Zhang, 2011 ; Rechtsman et al, 2013 ), topological semimetals (Jiang et al, 2015 ; Fang et al, 2016 ; Chang et al, 2017 ; Yan and Felser, 2017 ; Gao et al, 2019 ) with topological band inversion and exotic topological boundary states have attracted widespread attention. To date, many types of topological semimetals have been proposed, including topological nodal point semimetals (Liu et al, 2013 , 2019 ; Li et al, 2014 ; Xu et al, 2014 , 2016 , 2020 ; Dvorak and Wu, 2015 ; Cheng et al, 2017 ; Zhong et al, 2017 ; Gao et al, 2019 ; Zhang et al, 2019 ), topological nodal line semimetals (Cai et al, 2018 ; Chen et al, 2018 ; Gao et al, 2018 ; Zhou et al, 2018 ; He et al, 2019 ; Jin et al, 2019a ; Pham et al, 2019 ; Yi et al, 2019 ; Zou et al, 2019 ; Zhao et al, 2020 ), and topological nodal surface semimetals (Qie et al, 2019 ; Yang and Zhang, 2020 ).…”

Section: Introductionmentioning

confidence: 99%

Cubic Hafnium Nitride: A Novel Topological Semimetal Hosting a 0-Dimensional (0-D) Nodal Point and a 1-D Topological Nodal Ring

Xia

2020

Very recently, topological semimetals with nontrivial band crossing and associated topological surface states have received widespread attention. Various types of topological semimetals, including nodal point semimetals, nodal line semimetals, and nodal surface semimetals, have been predicted from first principles. In absence of spin-orbit coupling (SOC) effect, we propose that cubic-type hafnium nitride (HfN) with a space group is a novel topological semimetal hosting a rare 0-D triple nodal point and a 1-D topological nodal ring. More importantly, the interesting 0-D and 1-D topological states all occur near the Fermi level, and these topological states are not disturbed by other extraneous bands. When the SOC effect is taken into consideration, 0-D triple nodal point was gapped and a new 0-D topological element, namely, Dirac point appears along Γ-R path. Finally, the dynamical and mechanical stabilities of this semimetal and its associated mechanical properties are discussed in order to provide a reference for future investigations. Our work promises that HfN can serve as a superior topological semimetal with high stability, excellent mechanical properties, and rich topological states.