Dhirendra Kumar Pandey
PHYSICS
Janurary 2025
Quantum materials exhibit unique and exotic properties that diverge significantly from classical materials, offering significant promise for next-generation technological applications. This investigation explores the exotic conductivity of quantum materials, focusing on materials like topological insulators, Weyl semimetals, and high-temperature superconductors. By conducting both experimental and theoretical analyses, we aim to identify the mechanisms driving their unusual conductive behavior. Numerical simulations and experimental data were used to illustrate their conductive profiles under various temperature and magnetic field conditions. Results suggest that quantum coherence, topology, and electron correlation are central to their exotic conductivity, with implications for energy-efficient electronics and quantum computing
60- 67
© Airo Journals 2021
