The School aims at bringing together new ideas, novel results, problems and prospects of modern condensed matter physics with special focus on quantum technologies. The latter is new and advanced area of physics and engineering, based on the use some of the phenomena in quantum mechanics, such as quantum entanglement, quantum superposition and quantum tunneling and interference effects for practical applications such as quantum computing, quantum sensing, quantum cryptography, high precision quantum metrology and quantum imaging.
Topics: Graphene, two-dimensional materials and their heterostructures; Majorana fermions; Topological insulators; Quantum Hall effect; Novel superconducting materials; Quantum entanglement and quantum computing; Quantum networks and their applications; Quantum optics and cold atoms; Quantum metrology.
Topics: Nuclear level density, Gamma-ray strength function, Phase transitions in mesoscopic systems, Applications in astrophysics and reactor physics, Other related topics
Topics: Resources for quantum computing; quantum entanglement, etc., Quantum computing, in particular quantum interactive proof systems, etc., Quantum error-correcting codes, fermion and topological systems, Tensor networks and measurement-based quantum computing, Quantum supremacy in non-universal quantum computing, Quantum cryptography protocol; e.g., blind quantum computing, etc., Entanglement entropy in quantum field theory, Relations between gauge/gravity correspondence and entanglement entropy, New inequalities in quantum gravity theory from quantum information theory,, Fundamental principle of gauge/gravity correspondence and tensor networks Connections between gauge/gravity correspondence and quantum error-correcting codes, Black hole information paradox and quantum information theory, Complexity of states in quantum field theory and gauge/gravity correspondence