Attend an advanced school and workshop covering fundamental topics in quantum science and quantum technologies at a graduate and postdoctoral level. Explore cutting-edge theoretical and experimental aspects of quantum physics through comprehensive lectures on entanglement, coherence, correlations, quantum information, computation, sensing, estimation, and metrology. Delve into specialized areas including quantum simulations, quantum thermodynamics, quantum information in condensed matter physics, open quantum systems, algorithms and optimization, ultracold atoms, trapped ions, circuit QED, photonics and photonic networks, and spintronics. Learn from leading international experts including researchers from ETH Zürich, Free University Berlin, École Normale Supérieure Paris, University of Stuttgart, and other prestigious institutions. Gain exposure to recent research results, current trends, and future perspectives in quantum technologies through both structured educational sessions and research-focused workshop presentations. Access detailed coverage of topological phases of matter, tensor networks, machine learning techniques for quantum many-body physics, multipartite entanglement, quantum bounds and estimation theory, and quantum information processing with superconducting circuits, making this program particularly valuable for advanced undergraduate students, PhD candidates, postdoctoral fellows, and junior researchers seeking comprehensive knowledge in quantum science and technology applications.

Syllabus

Correlations, Entanglement and Resources in Quantum Information Science - Lecture 1 & 2
Quantum Thermodynamics - Lecture 1
Topological Phases of Matter with Ultracold Atoms and Photons - Lecture 1
Quantum Information Science with Atomic Trapped Ions - Lecture 1
Correlations, Entanglement and Resources in Quantum Information - Lecture 3
Quantum Thermodynamics - Lecture 2
Quantum Information Science with Atomic Trapped Ions - Lecture 2
Topological Phases of Matter with Ultracold Atoms and Photons - Lecture 2
Quantum Bounds, Quantum Estimation, and Quantum Metrology - Lecture 1
Tentative: Correlations, Entanglement and Resources in Quantum Information - Lecture 5
Quantum Thermodynamics - Lecture 3
Quantum Information Science with Atomic Trapped Ions - Lecture 3
Quantum Bounds, Quantum Estimation, and Quantum Metrology - Lecture 2
Topological Phases of Matter with Ultracold Atoms and Photons - Lecture 3 & 4
Tensor Networks - Lecture 1
Introduction to Ultracold Atoms in Quantum Technologies - Lecture 1
Multipartite Entanglement - Lecture 1
Quantum Bounds, Quantum Estimation, and Quantum Metrology - Lecture 3
Quantum Information Science with Atomic Trapped Ions - Lecture 4
Tensor Networks - Lecture 2
Quantum Information Processing with Superconducting Circuits - Lecture 1
Multipartite Entanglement - Lecture 2
Introduction to Ultracold Atoms in Quantum Technologies - Lectures 2 & 3
Machine Learning Techniques for Quantum Many-Body Physics - Lecture 1
Quantum Information Processing with Superconducting Circuits - Lecture 2
Tensor Networks - Lecture 3
Machine Learning Techniques for Quantum Many-Body Physics - Lecture 2
Multipartite Entanglement - Lecture 3
Machine Learning Techniques for Quantum Many-Body Physics - Lecture 3
Quantum Information Processing with Superconducting Circuits - Lecture 3
Tensor Networks - Lecture 4
Introduction to Ultracold Atoms in Quantum Technologies - Lecture 4