Quantum Electrodynamics in an Electrolyte Medium Driving Entanglement Between Graphene Sheets

TL;DR

This study demonstrates room-temperature quantum entanglement between graphene sheets in an electrolyte medium driven by time-dependent electric perturbations, highlighting a novel electrochemical approach to quantum phenomena.

Contribution

It introduces a new experimental method to observe quantum electrodynamics and entanglement in graphene systems within electrolytic media at room temperature.

Findings

Quantum entanglement observed at room temperature.

Electrochemical modulation mediates entanglement.

Method applicable to studying Weyl semi-metal structures.

Abstract

The quantum entanglement phenomenon was demonstrated to operate on a bipartite entangled system composed of two single layers of graphene embedded in an electrolytic medium (which did not permit the transport of electrons) and subjected to an external time-dependent electric perturbation driven by a potentiostat equipped with a frequency response analyser. Time-dependent perturbation-mediating entanglement was hypothesised because of the equivalent quantum resistive-capacitive circuit frequency of each single-layer graphene system that obeys quantum electrodynamics principles. \textit{De facto}, quantum electrodynamics, associated with the massless fermionic characteristics in graphene sheets, was observed at room temperature and electrolyte medium under a time-dependent modulation, and the entanglement between the two sheets is consistent with a Hilbertian subspace mathematical examination of the phenomenon. Remarkably, this experiment, among numerous other quantum electrochemical experiments conducted by this research group that follow quantum electrodynamics principles, highlights the generality of the methodology for studying entanglement phenomena, leading to alternative methods for investigating Weyl semi-metal structures and designing room-temperature quantum applications.