Statistical mechanics provides a framework for describing the physics of large, complex
many-body systems using only a few macroscopic parameters to determine the state of the …

Quantum computing is an exciting field that uses quantum principles, such as quantum
superposition and entanglement, to tackle complex computational problems …

We study the dynamics and thermalization of the Fredkin spin chain, a system with local
three-body interactions, particle conservation, and explicit kinetic constraints. We consider …

We study the stability of localization under periodic driving in Stark many-body systems. We
find that localization is stable except near special resonant frequencies, where resonances …

Discrete time crystalline phases have attracted significant theoretical and experimental
attention in the last few years. Such systems require a seemingly impossible combination of …

We study bulk particle transport in a Fermi-Hubbard model on an infinite-dimensional Bethe
lattice, driven by a constant electric field. Previous numerical studies showed that one …

Many-body localization in disordered systems in one spatial dimension is typically
understood in terms of the existence of an extensive number of (quasi) local integrals of …

Lattice gauge theories, the discretized cousins of continuum gauge theories, have become
an important platform for the exploration of non-equilibrium phenomena beyond their …

Correlated quantum systems feature a wide range of nontrivial effects emerging from
interactions between their constituent particles. In nonequilibrium scenarios, these manifest …

We study the dynamics and thermalization of the Fredkin spin chain, a system with local
three-body interactions, particle conservation and explicit kinetic constraints. We consider …