Spin Entanglement -- A Unifying Principle for Superconductors and Molecular Bonding

TL;DR

This paper extends the spin-statistics theorem to include quantum entanglement, proposing that isotropic spin-correlated states underpin phenomena like superconductivity and molecular bonding, unifying these concepts through spin entanglement.

Contribution

It introduces a novel theoretical framework linking spin entanglement to pairing phenomena in superconductors and molecular bonds, providing a unifying principle across multiple quantum systems.

Findings

ISC states occur in pairs, either parallel or anti-parallel

Experimental evidence supports the role of ISC states in superconductivity and bonding

The framework unifies diverse quantum phenomena through spin entanglement

Abstract

The spin-statistics theorem is generalized to include quantum entanglement. Specifically, within the context of spin entanglement, we prove that isotropic spin-correlated (ISC) states must occur in pairs. This pairing process can be composed of parallel or anti-parallel states. Consequently, the article proposes using ISC states as a unifying principle to explain better Bose-Einstein condensates, the theory of superconductivity, and molecular and atomic orbitals, all of which involve a pairing process. The theoretical framework is established in sections 1 and 2. The other qualitative sections focus primarily on the experimental evidence to support the theory.