Prediction of two-dimensional nodal-line semimetals in a carbon nitride covalent network

Chen, Haiyuan; Zhang, Shunhong; Jiang, Wei; Zhang, Chunxiao; Guo, Heng; Liu, Zheng; Wang, Zhiming; Liu, Feng

doi:10.1039/c8ta02555j

Cited by 109 publications

(83 citation statements)

References 74 publications

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“…We note that hopping terms can also be tuned by a chain of waveguide 20,49 , which could possibly be used to tune the band dispersion to realize the transition between type-I and type-II Dirac states. On the other hand, the Lieb and Kagome lattices have been separately proposed in real material systems, such as the 2D metal-organic and covelent-organic frameworks (MOF/COF) 24,[50][51][52][53] . Considering the high tunability of the MOF/COFs 54,55 , it is also possible to find suitable real 2D material systems to realize such phase transition.…”

Section: Photonic Waveguide Systemmentioning

confidence: 99%

Topological band evolution between Lieb and kagome lattices

et al. 2019

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Among two-dimensional lattices, both Kagome and Lieb lattices have been extensively studied, showing unique physics related to their exotic flat and Dirac bands. Interestingly, we realize that the two lattices are in fact interconvertible by applying strains along the diagonal direction, as they share the same structural configuration in the unit cell, i.e., one corner-site and two edge-center states. We study phase transitions between the two lattices using the tight-binding approach and propose one experimental realization of the transitions using photonic devices. The evolution of the band structure demonstrates a continuous evolution of the flat band from the middle of the Lieb band to the top/bottom of the Kagome band. Though the flat band is destroyed during the transition, the topological features are conserved due to the retained inversion symmetry, as confirmed by Berry curvature, Wannier charge center, and edge state calculations. Meanwhile, the triply degenerate Dirac point (M ) in the Lieb lattice transforms into two doubly degenerate Dirac points with one of which moves along M -Γ and the other moves along M -K/K directions that form the Kagome band eventually. Interestingly, the Dirac cones in the transition states are strongly tilted, showing a coexistence of type-I and type-II Dirac points. We finally show that these transitions can be experimentally realized in photonic lattices using waveguide arrays.

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Section: Photonic Waveguide Systemmentioning

confidence: 99%

Topological band evolution between Lieb and kagome lattices

et al. 2019

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“…Topological nodal point semimetals (Hosur et al, 2012 ; Zyuzin and Burkov, 2012 ; Hosur and Qi, 2013 ; Vazifeh and Franz, 2013 ; Liu et al, 2014 ; Lundgren et al, 2014 ; Kobayashi and Sato, 2015 ; Miransky and Shovkovy, 2015 ; Xu et al, 2015a ; Young and Kane, 2015 ) enjoy 0-D nodal points in momentum space. 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 ) host 1-D topological nodal lines in momentum space via band crossing along a line in momentum space. Topological nodal surface semimetals (Wu et al, 2018 ; Zhang et al, 2018 ; Fu et al, 2019a ; Qie et al, 2019 ; Yang et al, 2020 ) host 2-D nodal surface states that are composed of continuous band crossing points.…”

Section: Introductionmentioning

confidence: 99%

The Tetragonal Monoxide of Platinum: A New Platform for Investigating Nodal-Line and Nodal-Point Semimetallic Behavior

Xia

Srivastava

2020

Front. Chem.

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The search for new topological materials that are realistic to synthesize has attracted increasing attention. In this study, we systematically investigated the electronic, mechanical, and topological semimetallic properties, as well as the interesting surface states, of the tetragonal monoxide of platinum, which is realistic to synthesize, via a first-principles approach. Our calculated results indicate that PtO is a novel topological semimetal with double nodal lines in the k z = 0 plane and a pair of triple topological nodal points along the A'-M-A directions. Obvious surface states, including Fermi arc and drum-head-like surfaces, could be found around nodal points and nodal lines. The dynamic and mechanical stabilities of P4 2 /mmc-type PtO were examined in detail via calculation of the phonon dispersion and determination of elastic constants, respectively. Some other mechanical properties, including the bulk modulus, Young's modulus, shear modulus, Poisson's ratio, and Pugh's index, were considered in this study. P4 2 /mmc-type PtO provides a good research platform for investigation of novel behaviors that combine mechanical properties and rich topological elements.

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“…Weyl and Dirac materials (Ouyang et al, 2016 ; Zhong et al, 2016 ; Zhou et al, 2016 ; Liu et al, 2017 ; Fu et al, 2018 ; Meng et al, 2019 , 2020a ; Zhang et al, 2020 ), which host 2-fold and fourfold degenerate band-crossing points, have been explored in real materials and their exotic properties have been confirmed in experiments. Moving forward, a series of three-dimension materials, with 1D and 2D band crossing points, have been predicted to be nodal line semimetals/metals (Phillips and Aji, 2014 ; Gan et al, 2017 ; Jin et al, 2017 , 2019 , 2020 ; Lu et al, 2017 ; Yang et al, 2017 ; Chen et al, 2018 ; Gao et al, 2018 ; Liu et al, 2018 ) and nodal surface semimetals/metals (Wu et al, 2018 ; Zhang et al, 2018 ; Wang et al, 2020 ), respectively.…”

Section: Introductionmentioning

confidence: 99%

Pure Zirconium: Type II Nodal Line and Nodal Surface States

Zhang

Wang

2020

Front. Chem.

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Type II nodal line states have novel properties, such as direction-reliant chiral anomalies and high anisotropic negative magneto-resistance. These type II nodal line states have been widely investigated. Compared to nodal line materials, there are far fewer proposed nodal surface materials, and furthermore, a very recent challenge is to find a realistic material that co-exhibits both nodal line and nodal surface states. In this manuscript, we present the study of the electronic and topological states of pure zirconium within the density functional theory. We found that pure Zr is an interesting material that rarely exhibits both the type II nodal line state (in k z = 0 plane) and nodal surface state (in k z = π plane). The nontrivial topological states are explained based on the orbital-resolved band structures. Our study shows that pure Zr can serve as a new platform to investigate the interplay between the nodal line state and the nodal surface state.

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Prediction of two-dimensional nodal-line semimetals in a carbon nitride covalent network

Cited by 109 publications

References 74 publications

Topological band evolution between Lieb and kagome lattices

Topological band evolution between Lieb and kagome lattices

The Tetragonal Monoxide of Platinum: A New Platform for Investigating Nodal-Line and Nodal-Point Semimetallic Behavior

Pure Zirconium: Type II Nodal Line and Nodal Surface States

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