A new study has uncovered the universal dynamics far from equilibrium in randomly interacting spin models, thereby complementing the well-established universality in low-energy equilibrium physics.

In the intricate realm of wave turbulence, where predictability falters and chaos reigns, a groundbreaking study has emerged. The new research explores the heart of wave turbulence using an ultracold ...

Scientists from the Institute of Physics of the Chinese Academy of Sciences, along with their collaborators, have conducted a random multipolar driving experiment on a large, two-dimensional ...

Low-temperature plasmas are intrinsically non-equilibrium systems in which electromagnetic fields, particle transport, and thermodynamic processes interact ...

Quantum dynamics—the study of how particles behave and interact in a quantum system—has long fascinated physicists due to its puzzling and sometimes bizarre behaviors. Unlike classical systems, where ...

Time-dependent driving has become a powerful tool for creating novel non-equilibrium phases such as discrete time crystals and Floquet topological ...

The goal of this project is to construct a statistical morphing continuum theory to model the complex and non-equilibrium physics of microstructured eddies in compressible turbulence. This multiscale ...

Light and matter can remain at separate temperatures even while interacting with each other for long periods, according to new research that could help scale up an emerging quantum computing approach ...