Long-range quantum energy teleportation and distribution on a hyperbolic quantum network

TL;DR

This paper proposes a hybrid quantum energy teleportation method utilizing hyperbolic geometry to enable long-range energy distribution across large quantum networks, combining quantum state teleportation with energy transfer techniques.

Contribution

It introduces a novel hybrid approach for quantum energy teleportation on hyperbolic networks, allowing energy transfer over large distances independently of physical separation.

Findings

The method enables energy teleportation across large quantum networks.

Hyperbolic geometry facilitates exponential node growth for energy distribution.

The approach offers new possibilities for large-scale quantum network applications.

Abstract

Teleporting energy to remote locations is new challenge for quantum information science and technology. Developing a method for transferring local energy in laboratory systems to remote locations will enable non-trivial energy flows in quantum networks. From the perspective of quantum information engineering, we propose a method for distributing local energy to a large number of remote nodes using hyperbolic geometry. Hyperbolic networks are suitable for energy allocation in large quantum networks since the number of nodes grows exponentially. To realise long-range quantum energy teleportation, we propose a hybrid method of quantum state telepotation and quantum energy teleportation. By transmitting local quantum information through quantum teleportation and performing conditional operations on that information, quantum energy teleportation can theoretically be realized independent of geographical distance. The method we present will provide new insights into new applications of future large-scale quantum networks and potential applications of quantum physics to information engineering.