The topology and robustness of two Dirac cones in S-graphene: A tight binding approach

Bandyopadhyay, Amitava; Datta, Sujoy; Jana, Debnarayan; Nath, S.; Uddin, M. M.

doi:10.1038/s41598-020-59262-2

Cited by 47 publications

(28 citation statements)

References 45 publications

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“…Therefore, this insulating phase is distinct from the conventional insulators and we call this phase as topologically non-trivial phase. The systems with Chern numbers ±1 are sometimes referred as Chern insulators [27,34].…”

Section: Topological Phase and Associated Symmetriesmentioning

confidence: 99%

Dirac Materials in a MatrixWay

Bandyopadhyay¹,

Jana²

2020

ujms

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Recent years have been the platform of discovery of a wide range of materials, like d-wave superconductors, graphene, and topological insulators. These materials do indeed share a fundamental similarity in their low-energy spectra namely the fermionic excitations. There carriers behave as massless Dirac particles rather than conventional fermions that obey the usual Schrödinger Hamiltonian. A surprising aspect of most Dirac materials is that many of their physical properties measured in experiments can be understood at the non-interacting level. In spite of the large effective coupling constant in case of graphene, it has been observed that the interactions do not seem to play a major key role. Controlling the electrons at Dirac nodes in the first Brillouin zone needs the interplay of sublattice symmetry, inversion symmetry and the time-reversal symmetry. In this article, we have used explicit fundamental symmetry to understand the basic features of Dirac materials occurring in three diverse systems in a compact 2 × 2 matrix way. Furthermore, the robustness of the Dirac cones has also been explored from the scientific notion of topological physics. In addition, an elementary introduction on the three dimensional (3D) topological insulators and d wave superconductors will shed light in their respective fields. Furthermore, we have also discussed the way to evaluate the effective mass tensor of the carriers in the two dimensional (2D) Dirac materials. This methodology has also been critically extended to three dimensional (3D) topological insulators and d wave superconductors.

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Section: Topological Phase and Associated Symmetriesmentioning

confidence: 99%

Dirac Materials in a MatrixWay

Bandyopadhyay¹,

Jana²

2020

ujms

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“…In 2012, Wang et al established the stability and electronic characteristics of the armchair and zigzag T-graphene nanoribbons . Besides, extensive research has revealed applications of T-graphene in various intriguing fields, such as in gas sensors, , hydrogen storage, , current rectification devices, and optoelectronic devices. − Similar to graphene, the hexagonal forms of Si and Ge are the next two stable candidates from the same group. − One of the major advantages of working with silicene and germanene is that considering the spin–orbit coupling effects, the zero-band-gap feature can be avoided. , Recently, the tetragonal counterparts of Si and Ge, i.e., T-Si and T-Ge, have been predicted to be stable on satisfying various stability criteria. − Contrary to planar T-graphene, T-Si and T-Ge possess semimetallic band structures with double Dirac cones. , To generate and tune the band gap in these tetragonal systems, several approaches have been taken. , Hence, relative to T-graphene, T-Si and T-Ge are expected to be better candidates for nanodevice applications.…”

Section: Introductionmentioning

confidence: 99%

Tetragonal Silicene and Germanene Quantum Dots: Candidates for Enhanced Nonlinear Optical and Photocatalytic Activity

Ghosal

Nath²,

Bandyopadhyay

et al. 2021

J. Phys. Chem. C

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Over the past decade, quantum dots (QDs), based on two-dimensional (2D) materials have gained interest due to their numerous applications in the field of photonics. In this study, tetragonal silicene (T-Si) and tetragonal germanene (T-Ge) QDs with different shapes and sizes are systematically analyzed within the ab initio framework. All of these energetically favorable QDs are well suited for experimental design. In particular, these QD structures exhibit a range of electronic energy gaps depending upon specific morphology, which leads to enhanced nonlinear optical (NLO) characteristics in a broad spectrum. Moreover, the signature Raman modes of T-Si and T-Ge sheets have been critically explored by performing vibrational analysis of these QDs. These QDs also show optical absorption in the visible range and better light-harvesting efficiency, owing to which they can be helpful in designing solar cells. Outstanding second- and third-order NLO responses, such as second harmonic generation, optical Pockels effect, and Kerr effect in the presence of a perturbing external field, make these QD materials potentially efficient in the nonlinear optical field and photonics application. Furthermore, these QDs can participate in metal-free water splitting photocatalysis toward a pollutant-free green environment.

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“…Given these new features of non-Abelian charged degeneracies and multi-gap topological physics, a simple, intuitive, and easily tuneable, but experimentally viable system is of interest. A highlight candidate in this regard are classical spring-mass systems [38][39][40][41][42][43][44][45]. Especially because, if a spring-mass system is constituted in three-dimensional real space, it may exhibit nodal line degeneracies that can have an intricate interplay with non-Abelian charges [22,26].…”

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confidence: 99%

“…Here, we predict phase transitions of multi-gap nodal lines quantified by Euler class using a class of simple and easily realizable spring-mass systems. The non-Abelian charged nodal lines are realized using phonon waves in a classical spring-mass system [38][39][40][41][42][43][44][45][68][69][70][71][72][73][74]. A unit cell of our system consists of only one mass and several springs, and the system's mechanical behavior is thus described by classical mechanical equations of motion.…”

mentioning

confidence: 99%

“…A unit cell of our system consists of only one mass and several springs, and the system's mechanical behavior is thus described by classical mechanical equations of motion. Some springs concerning on-site potentials [42][43][44][45][72][73][74] eliminate the degeneracy at the Γ-point and enable a three-band nodal link. This heuristically amounts to removing the Nambu-Goldstone zero modes [37] by having different on-site potential.…”

mentioning

confidence: 99%

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Phase transitions of non-Abelian charged nodal links in a spring-mass system

Park,

Wong,

Bouhon

et al. 2022

Preprint

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Although a large class of topological materials have uniformly been identified using symmetry properties of wave functions, the past two years have seen the rise of multi-gap topologies beyond this paradigm. Given recent reports of unexplored features of such phases, platforms that are readily implementable to realize them are therefore desirable. Here, we demonstrate that multi-gap topological phase transitions of non-Abelian charged nodal lines arise in classical phonon waves. By adopting a simple spring-mass system, we construct nodal lines of a three-band system. The braiding process of the nodal lines is readily performed by adjusting the spring constants. The generation and annihilation of the nodal lines are then analyzed using Euler class. Finally, we retrieve topological transitions from trivial nodal lines to a nodal link. Our work provides a simple platform that can offer diverse insights to not only theoretical but also experimental studies on multi-gap topology.

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The topology and robustness of two Dirac cones in S-graphene: A tight binding approach

Cited by 47 publications

References 45 publications

Dirac Materials in a MatrixWay

Dirac Materials in a MatrixWay

Tetragonal Silicene and Germanene Quantum Dots: Candidates for Enhanced Nonlinear Optical and Photocatalytic Activity

Phase transitions of non-Abelian charged nodal links in a spring-mass system

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