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Rotation, Electric-Field Responses, and Absolute Enantioselection in Chiral Crystals

Rikuto Oiwa, Hiroaki Kusunose

2022Physical Review Letters39 citationsDOI

Abstract

The microscopic origin of chirality, possible electric-field induced static rotational lattice deformation, and rotation-field induced electric polarization are investigated. By building up a realistic tight-binding model for the elemental Te crystal in terms of a symmetry-adapted basis, we identify the microscopic origin of the chirality and essential couplings among polar and axial vectors with the same time-reversal properties. Based on this microscopic model, we elucidate quantitatively that an interband process, driven by nearest-neighbor spin-dependent imaginary hopping, is the key factor in the electric-field induced rotation and its inverse response. From the symmetry point of view, these couplings and responses are characteristic and common to any chiral material, leading to a possible experimental approach to achieve absolute enantioselection by simultaneously applied electric and rotation fields, or a magnetic field and electric current, and so on, as a conjugate field of the chirality.

Topics & Concepts

Electric fieldPhysicsChirality (physics)Condensed matter physicsRotation (mathematics)Polarization densityMagnetic fieldQuantum mechanicsMagnetizationSymmetry breakingSpontaneous symmetry breakingGeometryMathematicsNambu–Jona-Lasinio modelMolecular spectroscopy and chiralitySpectroscopy and Quantum Chemical StudiesSolid-state spectroscopy and crystallography
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