A5064112066- Advanced Battery Materials and Technologies
- Thermal Expansion and Ionic Conductivity
- Cloud Computing and Resource Management
- Thermal properties of materials
- Distributed and Parallel Computing Systems
- Rare-earth and actinide compounds
- Computational Physics and Python Applications
- Iron-based superconductors research
- Quantum Computing Algorithms and Architecture
- Advanced Thermoelectric Materials and Devices
- Physics of Superconductivity and Magnetism
Jan Długosz University
2014-2016
Institute of Physics
2014-2016
The thermodynamic properties of a SrPt3P compound in the superconducting state have been investigated by taking Eliashberg approach. anti-perovskite is identified as strong-coupling (λ = 1.33) s-wave superconductor with , where zero-temperature energy gap () obtained from calculations 3.15 meV. critical temperature TC was recently reported to be 8.4 K and this paper confirms Coulomb pseudopotential repulsions equal 0.123. Moreover, free difference between normal has calculated. On basis...
We investigate the thermodynamic parameters of superconducting antiperovskite CdCNi $$_3$$ using Eliashberg approach which is an excellent tool to exact characterization conventional superconductors. In particular, we reproduce measured transition temperature ( $$T_\mathrm{C}=3.2$$ K) for a high value Coulomb pseudopotential $$\mu ^{\star }_{\mathrm{C}}=0.22$$ ). Then determine energy gap, critical field and specific heat normal state. On this basis, show that properties differ slightly from...
In order to perform larger scale physics research in the area of superconductivity, we have developed an application that can transform Hubbard Hamiltonian into a matrix and diagonalize it find selected model's energy spectrum.For purpose used Python language its wide ecosystem.This paper proves tools are capable creating scientific applications general sense.After short introduction problem designed algorithm will present computer science problems their solutions usual programs, particular:...