Possible Routes to Frictionless Transport of Electronic Fluids in High-Temperature Superconductors

TL;DR

This paper explores how shear-thinning can enable frictionless electronic fluid transport in amorphous superconductors, potentially leading to high-temperature superconductivity by analyzing critical transport properties.

Contribution

It introduces a verified approach to study electronic fluid transport in amorphous materials and links critical temperatures to superconducting temperatures through activation energies.

Findings

Critical temperatures align with superconducting temperatures.

Shear-thinning enhances the possibility of high-temperature superconductivity.

Electronic fluids exhibit nearly frictionless transport under specific conditions.

Abstract

Electric-field-driven transport of electronic fluids in metallic glasses as well as three-dimensional amorphous superconductors are investigated by using the verified approach which has been successfully adopted to study the critical transport of glassy solid helium in very low temperature environment. The critical temperatures related to the nearly frictionless transport of electronic fluids were found to be directly relevant to the superconducting temperature of amorphous superconductors after selecting specific activation energies. Our results imply that optimal shear-thinning is an effective way to reach high-temperature charged superfluidity or superconductivity.