Explore quantum many-body dynamics in the era of Noisy, Intermediate-Scale Quantum (NISQ) devices through this 54-minute lecture by Wenwei Ho from PCS Institute for Basic Science. Delve into the global efforts in quantum computing technologies and their potential for investigating quantum many-body physics beyond conventional material experiments. Discover how these platforms enable the probing of novel phenomena in dynamics, particularly a deeper form of quantum thermalization. Learn about the union of many-body and quantum information frameworks, and how they yield new insights into fundamental phenomena. Examine the concept of universal randomness as a resource for quantum information science applications, such as quantum state learning. Follow the syllabus covering topics like quantum simulators, measurements, probing quantum thermalization, understanding projected ensembles, quantum state k-designs, and experiments with the 1d Periodically-kicked Ising Model.
Overview
Syllabus
Intro
New technologies: Quantum Simulators
Measurements: taking global snapshots
Probing quantum thermalization with quantum simulators
Understanding the projected ensemble
Characterizing projected ensembles
Conjecture: a generalized statistical mechanical principle
Crash course: Quantum state k-designs
Experiments
1d Periodically-kicked Ising Model
What's special about this model?
Family of models exhibiting exact emergent quantum state designs
Generic dynamics breaks dual-unitarity
Constraints from dynamical purification
Summary
Taught by
PCS Institute for Basic Science
