Quantum Thermodynamics extends classical thermodynamics into the quantum regime, where quantum coherence, entanglement, and fluctuations become important. It studies energy exchange, work, heat, and entropy in microscopic quantum systems. Unlike classical systems, quantum systems can exist in superposition states, leading to new thermodynamic behavior. Quantum thermodynamics investigates the limits of energy conversion, efficiency, and irreversibility at the quantum scale. It is essential for understanding nanoscale engines, quantum refrigerators, and information-driven thermodynamic processes. This field also explores the relationship between information and entropy in quantum systems. Quantum thermodynamics provides fundamental insight into nonequilibrium processes and helps design efficient quantum technologies, linking statistical physics, information theory, and quantum mechanics.
Title : Photoaligned azodye nanolayers: New trends for liquid crystal devices
Vladimir Chigrinov, Hong Kong University of Science and Technology, Hong Kong
Title : Where is modern physics heading? Why constants of nature matter
Alexander Unzicker, Pestalozzi Gymnasium Munchen, Germany
Title : Global photochemical model CHARM-DE of the earth’s atmosphere for altitudes 0-130 km
Alexei Krivolutsky, Central Aerological Observatory (CAO), Russian Federation
Title : Nonlinear plasma wave excitation in cylindrical semiconductor waveguides
Amir Sohail, COMSATS University Islamabad, Pakistan
Title : Characterization of quaternary alloy
Yarub Al Douri, European Academy of Sciences, Belgium
Title : Using physics to eliminate implant infection in over 25000 patients to date
Thomas J Webster, Brown University, United States