Long-Time Relaxation of a Finite Spin Bath Linearly Coupled to a Qubit

We discuss the long-time relaxation of a qubit linearly coupled to a finite bath of N spins (two-level systems, TLSs), with the interaction Hamiltonian in rotating wave approximation. We focus on the regime N >> 1, assuming that the qubit-bath coupling is weak, that the range of spin frequencies is sufficiently broad, and that all the spins are initialized in the ground state. Despite the model being perfectly integrable, we make two interesting observations about the effective system relaxation. First, as one would expect, the qubit relaxes exponentially towards its zero-temperature state at a well characterized rate. Second, the bath spins, even when mutually coupled, do not relax towards a thermal distribution, but rather form a Lorentzian distribution peaked at the frequency of the initially excited qubit. This behaviour is captured by an analytical approximation that makes use of the property N >> 1 to treat the TLS frequencies as a continuum and is confirmed by our numerical simulations.

Automated summary

We discuss the long-time relaxation of a qubit linearly coupled to a finite bath of N spins (two-level systems, TLSs), with interesting observations about the effective system relaxation. Despite being perfectly integrable, the qubit relaxes exponentially towards its zero-temperature state, while the bath spins form a Lorentzian distribution peaked at the frequency of the initially excited qubit.