Interaction of a circularly polarised gravitational wave with a charged particle in a static magnetic background

Abstract

Interaction of a charged particle in a static magnetic background, i.e., a Landau system with circularly polarised gravitational wave (GW) is studied quantum mechanically in the long wavelength and low velocity limit. We quantize the classical Hamiltonian following speli. The rotating polarization vectors of the circularly polarized GW are employed to form a unique directional triad which served as the coordinate axes. The Schrodinger equations for the system are cast in the form of a set of coupled linear differential equations. This system is solved by iterative technique. We compute the time-evolution of the position and momentum expectation values of the particle. The results show that the resonance behaviour obtained earlieremgwclassical by classical treatements of the system has a quantum analogue not only for the linearly polarized GW emgw1lin, but for circularly polarized GW as well.