Dynamics of decoherence: universal scaling of the decoherence factor

Abstract

We study the time dependence of the decoherence factor (DF) of a qubit globally coupled to an environmental spin system (ESS) which is driven across the quantum critical point (QCP) by varying a parameter of its Hamiltonian in time t as 1 -t/τ or -t/τ, to which the qubit is coupled starting at the time t -∞; here, τ denotes the inverse quenching rate. In the limit of weak coupling, we analyze the time evolution of the DF in the vicinity of the QCP (chosen to be at t=0) and define three quantities, namely, the generalized fidelity susceptibility F(τ) (defined right at the QCP), and the decay constants α1 (τ) and α2 (τ) which dictate the decay of the DF at a small but finite t(>0). Using a dimensional analysis argument based on the Kibble-Zurek healing length, we show that F(τ) as well as α1 (τ) and α2(τ) indeed satisfy universal power-law scaling relations with τ and the exponents are solely determined by the spatial dimensionality of the ESS and the exponents associated with its QCP. Remarkably, using the numerical t-DMRG method, these scaling relations are shown to be valid in both the situations when the ESS is integrable and non-integrable and also for both linear and non-linear variation of the parameter. Furthermore, when an integrable ESS is quenched far away from the QCP, there is a predominant Gaussian decay of the DF with a decay constant which also satisfies a universal scaling relation.