Video URL
https://pirsa.org/21030016Quantum many-body dynamics in two dimensions with artificial neural networks
APA
Heyl, M. (2021). Quantum many-body dynamics in two dimensions with artificial neural networks. Perimeter Institute for Theoretical Physics. https://pirsa.org/21030016
MLA
Heyl, Markus. Quantum many-body dynamics in two dimensions with artificial neural networks. Perimeter Institute for Theoretical Physics, Mar. 05, 2021, https://pirsa.org/21030016
BibTex
@misc{ scivideos_PIRSA:21030016, doi = {10.48660/21030016}, url = {https://pirsa.org/21030016}, author = {Heyl, Markus}, keywords = {Quantum Information}, language = {en}, title = {Quantum many-body dynamics in two dimensions with artificial neural networks}, publisher = {Perimeter Institute for Theoretical Physics}, year = {2021}, month = {mar}, note = {PIRSA:21030016 see, \url{https://scivideos.org/index.php/pirsa/21030016}} }
Markus Heyl Max Planck Institute for the Physics of Complex Systems
Abstract
In the last two decades the field of nonequilibrium quantum many-body physics
has seen a rapid development driven, in particular, by the remarkable progress
in quantum simulators, which today provide access to dynamics in quantum
matter with an unprecedented control. However, the efficient numerical
simulation of nonequilibrium real-time evolution in isolated quantum matter
still remains a key challenge for current computational methods especially
beyond one spatial dimension. In this talk I will present a versatile and
efficient machine learning inspired approach. I will first introduce the
general idea of encoding quantum many-body wave functions into artificial
neural networks. I will then identify and resolve key challenges for the
simulation of real-time evolution, which previously imposed significant
limitations on the accurate description of large systems and long-time
dynamics. As a concrete example, I will consider the dynamics of the
paradigmatic two-dimensional transverse field Ising model, where we observe
collapse and revival oscillations of ferromagnetic order and demonstrate that
the reached time scales are comparable to or exceed the capabilities of state-
of-the-art tensor network methods.