Pathways toward understanding Macroscopic Quantum Phenomena

TL;DR

This paper explores the foundational aspects of macroscopic quantum phenomena, aiming to develop a theoretical framework by examining collective variables, entanglement persistence, and structural levels in large quantum systems.

Contribution

It proposes a systematic investigation into the foundations of macroscopic quantum phenomena, focusing on collective variables, correlation hierarchies, and quantum entanglement in large systems.

Findings

Quantum features can be captured by collective variables in macroscopic objects.

Quantum entanglement can persist at high temperatures and large scales under certain conditions.

Connectivity in quantum networks may decrease entanglement, challenging intuitive assumptions.

Abstract

Macroscopic quantum phenomena refer to quantum features in objects of `large' sizes, systems with many components or degrees of freedom, organized in ways where they can be identified as macroscopic objects. This emerging field is ushered in by several categories of definitive experiments in superconductivity, electromechanical systems, Bose-Einstein condensates and others. Yet this new field which is rich in open issues at the foundation of quantum and statistical physics remains little explored theoretically [1]. This talk summarizes our thoughts on attempting a systematic investigation into its foundation, with the goal of ultimately revealing or building a viable theoretical framework. Three major themes discussed in three intended essays are the large N expansion [2], the correlation hierarchy [3] and quantum entanglement [4]. We give a sketch of the first two themes and then discuss several key issues in the consideration of macro and quantum, namely, a) recognition that in a composite body there exist many 'levels of structure' characterized by collective variables. The quantum features of a macroscopic object can be captured by understanding how these collective variables function; b) 'quantum entanglement', an exclusively quantum feature [5], is known to persist to high temperatures [6] and large scales [7] under certain conditions, and may actually decrease with increased connectivity in a quantum network [8]. Here we use entanglement as a measure of quantumness and pick out these somewhat counter-intuitive examples to show that there are blind spots worthy of our attention and issues which we need to analyze closer. Our purpose is to try to remove the stigma that quantum only pertains to micro, in order to make way for deeper probes into the conditions whereby quantum features of macroscopic systems manifest.