International Conference on Mathematical Structures in Quantum Theory (ICMSQT - 26)

This track explores the mathematical foundations underlying quantum mechanics, focusing on the axiomatic structures and interpretations of quantum theory. Contributions may include discussions on measurement theory, state spaces, and the role of probability in quantum systems.

This session will delve into the role of operator algebras in the formulation of quantum mechanics and quantum field theory. Papers may address advancements in the algebraic approach to quantum systems and their implications for physical predictions.

This track focuses on the application of functional analysis in the study of quantum systems, particularly in relation to Hilbert spaces and spectral theory. Submissions may explore topics such as self-adjoint operators, spectral measures, and their physical interpretations.

This session aims to investigate the mathematical structures that underpin quantum information theory, including quantum entanglement and information processing. Contributions may include discussions on quantum algorithms, error correction, and the implications for classical information theory.

This track examines the interplay between quantum computation and algebraic structures, emphasizing the mathematical frameworks that facilitate quantum algorithms. Papers may focus on quantum circuits, gate operations, and the algebraic properties of quantum states.

This session will explore the application of spectral theory to quantum mechanics, particularly in the context of observables and their measurement. Submissions may cover topics such as the spectral decomposition of operators and the implications for quantum state evolution.

This track investigates geometric perspectives in quantum theory, including the use of differential geometry and topology in the analysis of quantum systems. Contributions may explore the geometric formulation of quantum mechanics and its implications for physical theories.

This session focuses on the mathematical rigor in quantum field theory, emphasizing the role of advanced mathematical techniques in understanding physical phenomena. Papers may discuss renormalization, perturbation theory, and the interplay between mathematics and physics.

This track examines the role of probability theory in quantum mechanics, particularly in relation to uncertainty and stochastic processes. Contributions may include discussions on quantum probabilities, Bell's theorem, and the implications for classical probability theory.

This session will explore various algebraic structures that arise in quantum mechanics, including groups, rings, and fields. Papers may focus on the implications of these structures for symmetry, conservation laws, and the mathematical formulation of quantum theories.

This track encourages interdisciplinary contributions that bridge mathematics with other fields related to quantum theory, such as computer science and information theory. Submissions may explore novel mathematical techniques and their applications in quantum research.