On the Mechanism of Above Room Temperature Superconductivity and Superfluidity by Relativistic Quantum Mechanics

TL;DR

This paper proposes a comprehensive relativistic quantum mechanics-based theory explaining various types of superconductivity and superfluidity, including at extremely high temperatures, and predicts room temperature superconductivity.

Contribution

It introduces a new classification of superconductivity and superfluidity types based on relativistic triple quasi-particles and explains recent nano-graphene observations.

Findings

Explains all known superconductivity and superfluidity trends.

Predicts room temperature superconductivity.

Models high-temperature superfluidity in relativistic terms.

Abstract

A comprehensive theory of superconductivity (SC) and superfluidity (SF) is presented of new types III and IV at temperatures into millions of degrees involving phase transitions of fermions in heat reservoirs to form general relativistic triple quasi-particles of 3 fermions interacting to boson-fermion pairs. Types 0, I, and II SC/SF are deduced from such triples as: thermally dressed, relativistic fermionic vortices; spin coupled, dressed, fermionic vortical pairs (diamagnetic bosons); and spinrevorbitally coupled, dressed fermionic, vortical pairs (ferromagnetic bosons). All known SC, SF and trends in critical temperatures (Tc) are thereby explained. The recently observed SC/SF in nano-graphene systems is explained. The above room temperature SC/SF is predicted and modeled by transformations of intense thermal boson populations of heat reservoirs to relativistic mass, weight, spin and magnetism for further reasoning over compression to electricity, weak phenomena and strong phenomena for connecting general relativism and quantum mechanics.