Explanation of Pressure Effect for High Temperature Superconductors Using Pressure Dependent Schrodinger Equation and String Theory
Open Access
- 1 January 2020
- journal article
- research article
- Published by Scientific Research Publishing, Inc. in Natural Science
- Vol. 12 (01), 28-34
- https://doi.org/10.4236/ns.2020.121004
Abstract
A pressure dependent Schrodinger equation is used to find the conditions that lead to superconductivity. When no pressure is exerted, the superconductor resistance vanishes beyond a critical temperature related to the repulsive force potential of the electron gass, where one assuming the electron total energy to be thermal, where applying mechanical pressure destroys Sc when it exceeds a certain critical value. However when the electron total energy is an assumed to be that of the free electron model and that the pressure is thermal and mechanical, the situation is different. The quantum expression for resistance shows that the increase of mechanical pressure increases the critical temperature. Such phenomenon is observed in high temperature cupper group.Keywords
This publication has 5 references indexed in Scilit:
- Pressure Effect on Superconducting Critical Temperature According to String ModelInternational Journal of Fluid Mechanics & Thermal Sciences, 2017
- New Derivation of Simple Josephson Effect Relation Using New Quantum Mechanical EquationNatural Science, 2016
- Crystal structure of High Temperature SuperconductorsSpringer Series in Materials Science, 2009
- Type II SuperconductivityPublished by Elsevier BV ,2007
- Linear approximationPublished by Elsevier BV ,1975