Explore the cutting-edge field of non-equilibrium quantum many-body systems through this comprehensive school featuring leading experts in quantum physics. Delve into the design and understanding of quantum many-body states that operate beyond conventional thermodynamics, with applications spanning from driven open systems to atomic, molecular, and optical (AMO) platforms. Master four key research areas: dissipative engineering of quantum correlated states at the intersection of AMO and solid-state physics, theoretical advances in quantum many-body information beyond the noisy intermediate-scale quantum (NISQ) era, modern ultracold atom and quantum optics simulators, and connections between condensed matter and high-energy physics in quantum information scrambling dynamics. Learn from expert instructors including Marcello Dalmonte on quantum simulation of lattice gauge theories, Darrick Chang on atom-light interactions as dissipative spin models, Hannes Bernien on quantum information processing with Rydberg atom arrays, Sebastian Diehl on driven open quantum systems, and Joaquin Nieva on universal prethermal dynamics in quantum magnets and fracton fluids. Gain both foundational knowledge and advanced insights into this rapidly evolving research area through lectures, tutorial sessions, and seminars that bridge interdisciplinary boundaries between quantum physics, condensed matter, and high-energy physics.

Syllabus

Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 01 of 06
Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 02 of 06
Marcello Dalmonte - Tutorial Session
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 01 of 06
Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 03 of 06
Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 04 of 06
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 02 of 06
Darrick Chang - Tutorial Session
Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 05 of 06
Marcello Dalmonte - Quantum Simulation of Lattice Gauge Theories - Class 06 of 06
Mohammad Ali Rajabpour - Minors or: how I learned to stop worrying and love the exponentia
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 03 of 06
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 04 of 06
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 05 of 06
Darrick Chang - Atom-Light Interactions as a Dissipative Spin Model - Class 06 of 06
Hannes Bernien: Quantum Information Processing and Simulation with Rydberg Atom Arrays - 01 of 03
Sebastian Diehl : Driven Open Quantum Systems — from Micro- to Macrophysics - Class 01 of 03
Rosario Fazio : Seminar
Joaquin Nieva: Universal Prethermal Dynamics in Quantum Magnets and Fracton Fluids - Class 01 of 03
Sebastian Diehl : Driven Open Quantum Systems — from Micro- to Macrophysics - Class 02 of 03
Joaquin Nieva: Universal Prethermal Dynamics in Quantum Magnets and Fracton Fluids - Class 02 of 03
Hannes Bernien: Quantum Information Processing and Simulation with Rydberg Atom Arrays - 02 of 03
Joaquin Nieva: Universal Prethermal Dynamics in Quantum Magnets and Fracton Fluids - Class 03 of 03
Hannes Bernien: Quantum Information Processing and Simulation with Rydberg Atom Arrays - 03 of 03
Sebastian Diehl : Driven Open Quantum Systems — from Micro- to Macrophysics - Class 03 of 03