Whenever a quantum environment emerges as a classical system, it behaves like a measuring apparatus

TL;DR

This paper demonstrates that when a quantum environment becomes large, its dynamics resemble a classical measuring apparatus, leading to decoherence and a universal evolution pattern regardless of specific interactions.

Contribution

It applies large-N quantum field theory concepts to open quantum systems, showing environments effectively behave classically and induce measurement-like decoherence.

Findings

Large-N conditions lead to classical-like environment behavior

Environment induces decoherence in a basis determined by interaction details

Universal measurement-like evolution occurs regardless of specific interactions

Abstract

We study the dynamics of a quantum system $\Gamma$ with an environment $\Xi$ made of $N$ elementary quantum components. We aim at answering the following questions: can the evolution of $\Gamma$ be characterized by some general features when $N$ becomes very large, regardless of the specific form of its interaction with each and every component of $\Xi$? In other terms: should we expect all quantum systems with a macroscopic environment to undergo a somehow similar evolution? And if yes, of what type? In order to answer these questions we use well established results from large-$N$ quantum field theories, particularly referring to the conditions ensuring a large-$N$ quantum model to be effectively described by a classical theory. We demonstrate that the fulfillment of these conditions, when properly imported into the framework of the open quantum systems dynamics, guarantees that the evolution of $\Gamma$ is always of the same type of that expected if $\Xi$ were a measuring apparatus, no matter the details of the actual interaction. On the other hand, such details are found to determine the specific basis w.r.t. which $\Gamma$ undergoes the decoherence dictated by the dynamical description of the quantum measurement process. This result wears two hats: on the one hand it clarifies the physical origin of the formal statement that, under certain conditions, any channel from $\rho_\Gamma$ to $\rho_\Xi$ takes the form of a measure-and-prepare map, as recently shown in Ref. [1]; on the other hand, it formalizes the qualitative argument that the reason why we do not observe state superpositions is the continual measurement performed by the environment.