Phase space dynamics and control of the quantum particles associated to hypergraph states

TL;DR

This paper explores phase space dynamics and control of quantum particles in hypergraph states, aiming to predict and manipulate their trajectories for improved quantum information transmission and noise reduction.

Contribution

It introduces a hypergraph network model for quantum communication, providing numerical solutions for quantum particle trajectories and control protocols.

Findings

Quantum particles follow controllable paths in phase space.

Protocols can reduce background noise in quantum systems.

Enhanced prediction of quantum particle trajectories.

Abstract

As today's nanotechnology focus becomes primarily oriented toward production and manipulation of materials at the subatomic level, allowing the performance and complexity of interconnects where the device density accepts more than hundreds devices on a single chip, the manipulation of semiconductor nanostructures at the subatomic level sets its prime tasks on preserving and adequate transmission of information encoded in specified (quantum) states. The presented study employs the quantum communication protocol based on the hypergraph network model where the numerical solutions of equations of motion of quantum particles are associated to vertices (assembled with device chip), which follow specific controllable paths in the phase space. We address these findings towards ultimate quest for prediction and selective control of quantum particle trajectories. In addition, presented protocols could represent valuable tool for reducing background noise and uncertainty in low-dimensional and operationally meaningful, scalable complex systems.