To the Non-Local Theory of the High Temperature Superconductivity

TL;DR

This paper explores a non-local physics approach to high-temperature superconductivity, proposing that soliton motion in lattice-ion-electron systems without chemical bonds could be key, and suggests quantum dot technology for material development.

Contribution

It introduces a non-local theoretical framework for high-temperature superconductivity based on soliton dynamics and quantum hydrodynamics, proposing new material design strategies.

Findings

Soliton motion can occur without chemical bonds in superconducting systems.

Quantum dots could enable the creation of materials supporting soliton-based superconductivity.

The non-local theory offers a new perspective on high-temperature superconductivity mechanisms.

Abstract

The possibility of the non local physics application in the theory of superconductivity is investigated. It is shown that by the superconducting conditions the relay ("estafette") motion of the soliton' system ("attice ion - electron") is realizing by the absence of chemical bonds. From the position of the quantum hydrodynamics the problem of creation of the high temperature superconductors leads to finding of materials which lattices could realize the soliton' motion without destruction. These materials should be created using the technology of quantum dots. Key words: Foundations of the theory of transport processes; The theory of solitons; Generalized hydrodynamic equations; Foundations of quantum mechanics; high temperature superconductivity.