Covers the interpretation of the Lindblad equation and its unitary part in quantum gases.
Explores the Lindblad equation and the Markov approximation in quantum optics.
Explores NISQ devices and IBM Q, covering noisy quantum circuits, qubit technologies, and quantum algorithm development.
Delves into quantum entanglement, exploring entangled particles' state, evolution, and measurement.
Covers quantum entropy, density matrices, and entanglement in quantum information theory.
Covers the derivation and solutions of Optical Bloch Equations for a two-level quantum system.
Explores quantum measurements, including POVMS and general projections, and their applications in quantum computing.
Covers entropic notions in quantum sources, Shannon entropy, Von Neumann entropy, and source coding.
Explores the evolution of density matrices in quantum optics, emphasizing super-operators and completely positive maps.
Explores testing quantum systems in the high-complexity regime and the challenges of demonstrating quantum computational advantage.
Explores projective quantum measurements, system-meter formulation, observable outcomes, and coupling between systems and meters.
Covers quantum computing, simulation, sensing, and communications, highlighting EPFL's role in quantum science and engineering.
Covers the basics of quantum computing, focusing on superconducting qubits, scaling challenges, and potential applications.
