Symmetry-mode-based atomic scale formalism of lattice dynamics

Abstract

The authors present classical and quantum mechanical descriptions of lattice dynamics, from the atomic to the continuum scale, using atomic scale symmetry modes and their constraint equations. This approach is demonstrated for a one-dimensional chain and a two-dimensional square lattice with a monatomic basis. For the classical description, the authors find that rigid modes, in addition to the distortional modes found before, are necessary to describe the kinetic energy. The long-wavelength limit of the kinetic energy terms expressed in terms of atomic scale modes is shown to be consistent with the continuum theory, and the leading order corrections are obtained. For the quantum mechanical description, the authors find conjugate momenta for the atomic scale symmetry modes. In direct space, graphical rules for their commutation relations are obtained. Commutation relations in the reciprocal space are also calculated. As an example, phonon modes are analyzed in terms of symmetry modes. The authors briefly discuss how the approach presented here, based on atomic scale symmetry modes, could be useful for the study of atomic scale dynamics in solid–solid phase transitions in complex emergent materials, in which competition between structural phases and nonlinearity of the lattice energy plays an important role.