A map between time-dependent and time-independent quantum many-body Hamiltonians

Abstract

Given a time-independent Hamiltonian H, one can construct a time-dependent Hamiltonian Ht by means of the gauge transformation Ht=Ut H \, Ut-i\, Ut\, ∂t Ut. Here Ut is the unitary transformation that relates the solutions of the corresponding Schrodinger equations. In the many-body case one is usually interested in Hamiltonians with few-body (often, at most two-body) interactions. We refer to such Hamiltonians as "physical". We formulate sufficient conditions on Ut ensuring that Ht is physical as long as H is physical (and vice versa). This way we obtain a general method for finding such pairs of physical Hamiltonians Ht, H that the driven many-body dynamics governed by Ht can be reduced to the quench dynamics due to the time-independent H. We apply this method to a number of many-body systems. First we review the mapping of a spin system with isotropic Heisenberg interaction and arbitrary time-dependent magnetic field to the time-independent system without a magnetic field [F. Yan, L. Yang, B. Li, Phys. Lett. A 251, 289 (1999); Phys. Lett. A 259, 207 (1999)]. Then we demonstrate that essentially the same gauge transformation eliminates an arbitrary time-dependent magnetic field from a system of interacting fermions. Further, we apply the method to the quantum Ising spin system and a spin coupled to a bosonic environment. We also discuss a more general situation where H = Ht is time-dependent but dynamically integrable.