Nonseparability as Time-Averaged Dynamic States

TL;DR

This paper presents a novel framework that models quantum nonseparability as a time-averaged oscillatory process, offering new insights into entanglement and potential classical simulation methods.

Contribution

It introduces a simple mechanism using auxiliary frequencies to represent nonseparability as a dynamic, time-averaged phenomenon, bridging quantum entanglement and classical wave systems.

Findings

Nonseparability modeled as a time-averaged oscillatory process

Auxiliary frequencies act as coherence channels for entanglement

Potential for classical simulation of multipartite entanglement

Abstract

Nonseparability - multipartite states that cannot be factorized - is one of the most striking features of quantum mechanics, as it gives rise to entanglement and non-causal correlations. In quantum computing, it also contributes directly to the computational advantage of quantum computers over its digital counterparts. In this work, we introduce a simple mechanism that frames nonseparability as a time-averaged manifestation of an underlying oscillatory process within state space. The central idea is the inclusion of auxiliary angular frequencies that modulate the temporal evolution of composite states. These additional dynamical degrees of freedom act as coherence channels through which nonseparability is mediated. While the proposed formalism could eventually serve as an alternative theoretical handle on the mechanisms of quantum entanglement, its greater significance lies in opening practical routes for simulating multipartite entanglement in controlled classical wave systems.