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Topological states in superlattices of HgTe class of materials for engineering three-dimensional flat bands

Rajibul Islam, Barun Ghosh, Giuseppe Cuono, Alexander Lau, Wojciech Brzezicki, Arun Bansil, Amit Agarwal, Bahadur Singh, T. Dietl, Carmine Autieri

2022Physical Review Research20 citationsDOIOpen Access PDF

Abstract

In search of materials with three-dimensional flat band dispersions, using ab initio computations we investigate how topological phases evolve as a function of hydrostatic pressure and uniaxial strain in two types of superlattices: HgTe/CdTe and HgTe/HgSe. In short-period HgTe/CdTe superlattices, our analysis unveils the presence of isoenergetic nodal lines, which could host strain-induced three-dimensional flat bands at the Fermi level without requiring doping, when fabricated, for instance, as core-shell nanowires. In contrast, HgTe/HgSe short-period superlattices are found to harbor a rich phase diagram with a plethora of topological phases. Notably, the unstrained superlattice realizes an ideal Weyl semimetal with Weyl points situated at the Fermi level. A small-gap topological insulator with multiple band inversions can be obtained by tuning the volume: under compressive uniaxial strain, the material transitions sequentially into a Dirac semimetal to a nodal-line semimetal, and finally into a topological insulator with a single band inversion.

Topics & Concepts

SuperlatticeSemimetalTopological insulatorCondensed matter physicsElectronic band structureFermi levelMaterials scienceTopology (electrical circuits)Phase diagramHydrostatic pressureBand gapPhysicsPhase (matter)Quantum mechanicsMathematicsElectronThermodynamicsCombinatoricsTopological Materials and Phenomena2D Materials and ApplicationsGraphene research and applications