Macroscopic Quantum Phenomena from the Coupling Pattern and Entanglement Structure Perspective

TL;DR

This paper investigates how quantum entanglement between macroscopic objects depends on their internal structure, coupling patterns, and collective variables, revealing conditions for entanglement persistence and the special role of the center of mass.

Contribution

It provides a theoretical framework linking micro-constituent entanglement to macroscopic entanglement, highlighting the impact of coupling patterns and collective variables.

Findings

Entanglement in 1-to-1 coupling is independent of the number of constituents.

Center of mass coupling scales with the number of particles in 1-to-all coupling.

Entanglement between constituents can undergo sudden death, while center of mass entanglement can persist.

Abstract

We explore in this paper ways to qualify and quantify the quantum entanglement $E(M)$ between two macroscopic objects by way of model studies. Knowing that a macroscopic object is a composite, how does one determine $E(M)$ in terms of the entanglements between its micro-constituents $E(\mu)$? We assert that the notion of `levels of structure', the coupling strength between constituents in different levels, and the use of collective variables in each level are all pertinent factors. We consider two types of coupling, each constituent particle is coupled to only one other particle (1-to-1) versus it coupled to all particles (1-to-all). In the 1-1 case with pairwise interactions of equal strength, the entanglement is independent of the number of constituent particles $N$ in the macroscopic object. In the 1-to-all case the relative coordinates are decoupled and the center of mass (CoM) coupling scales with $N$. We provide a proof of the conditions whereby the CoM variable decouples, a cause for the special role the CoM variable plays in the entanglement between the two such macroscopic objects. This qualitative behavior is largely not affected by fluctuations in the interaction strength. We also analyzed the entanglement pattern of 4 coupled oscillators in two pairs, representing the two objects A and B (or two adjacent levels of structure), each with two constituents. By assigning different coupling strengths we can investigate the interplay of inter-level entanglement with intra- level interactions. From the entanglement dynamics of the 4-oscillator system with varying coupling strength we see the entanglement between constituents meeting sudden death while the CoM variables may sustain over longer times. This offers another way to determine under what conditions quantum entanglement between macroscopic objects can persist.