Enhancement of non-Markovianity due to environment-induced indirect interaction

TL;DR

This paper demonstrates that environment-induced indirect interactions among multiple two-level systems can significantly enhance non-Markovian effects, contrasting with the negligible effects observed in single-system pure dephasing under weak coupling.

Contribution

It reveals how collective interactions via a common environment can drastically increase non-Markovianity in multi-qubit systems, providing new insights into decoherence control.

Findings

Indirect interactions induce strong non-Markovianity.

Single-system dynamics remain Markovian under weak coupling.

Multi-system interactions qualitatively change non-Markovian behavior.

Abstract

Non-Markovian effects are often significant when the system-environment coupling is not weak. Indeed, we find that the non-Markovianity is negligible for a single two-level system undergoing pure dephasing via a weak interaction with a harmonic-oscillator environment. In this paper, we show that, within the framework of pure dephasing, the non-Markovianity displayed by a two-level system can, in fact, be far more pronounced. To demonstrate that this is indeed the case, we consider a pure dephasing model where a collection of two-level systems interacts with a common environment. We obtain analytically the dynamics of the collection of the two-level systems, and then take a partial trace over all the two-level systems except one. This remaining single two-level system exhibits markedly non-Markovian dynamics, even when the system-environment coupling is weak. This is due to the indirect interaction between the two-level systems, induced by their interaction with the common environment. In fact, this indirect interaction can not only increase the non-Markovianity by orders of magnitude, but also qualitatively change the characteristics of the non-Markovian behavior. For instance, for a single two-level system undergoing pure dephasing, the dynamics are Markovian for both Ohmic and sub-Ohmic environments. This is markedly not the case when we consider multiple two-level systems. These findings provide insights into controlling decoherence in multi-qubit quantum systems and have implications for quantum technologies where non-Markovianity can be a resource rather than a limitation.