Topological Quantum States
Topological Quantum States are phases of matter characterized by global, topological properties rather than local order parameters. These states are robust against local perturbations and disorder, making them highly stable. Examples include topological insulators and superconductors, which exhibit protected edge or surface states. The unique properties of topological quantum states arise from the topology of the system’s wave functions. They play a major role in modern condensed matter physics and quantum materials research. Topological states have potential applications in fault-tolerant quantum computation due to their inherent stability. Their discovery has expanded the classification of phases of matter beyond traditional symmetry-based frameworks. Topological quantum states represent a major paradigm shift in understanding quantum materials.
Thomas F Ramos
Lawrence Livermore National Laboratory, United States
Ephraim Suhir
Portland State University, United States
Alexander Unzicker
Pestalozzi Gymnasium Munchen, Germany
Thomas J Webster
Brown University, United States
Jon H Brasher
Stelleo Scientific Foundation, United States
Jason Liu
West Windsor-Plainsboro High School North, United States
Tom Lawrence
Ronin Institute of Independent Scholarship 2.0, United KingdomSubmit your abstract Today
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