Using an advanced Monte Carlo method, Caltech researchers found a way to tame the infinite complexity of Feynman diagrams and ...

A clever method from Caltech researchers now makes it possible to unravel complex electron-lattice interactions, potentially transforming how we understand and design quantum and electronic materials.

The final result from the Muon g-2 Experiment has exceeded all expectations, achieving a precision likely to remain unmatched ...

"Remarkable" new model of quantum double-exchange ferromagnets could produce fresh insights into these technologically-important materials ...

Their most recent paper, published in Nature Physics, reports the emergence of ferromagnetism at the onset of a density-tuned Kondo breakdown in MoTe 2 /WSe 2 moiré bilayers. "Our work builds on ...

Twisted materials—known as moiré structures—have revolutionized modern physics, emerging as today's "alchemy" by creating ...

Our results exemplify the strong correspondence between the optical lattice physics of ultracold bosonic atoms and the Bose–Hubbard model1,2—a link that is vital for future applications of ...

Mathematical solutions to thorny quantum problems can be found more quickly by exploiting the correspondence between the statistical methods used in deep learning and techniques for implementing ...

Hidetoshi Yatori and Jun Ye won the 2022 Breakthrough Prize in Fundamental Physics "for outstanding contributions to the invention and development of the optical lattice clock, which enables ...

I've always been fascinated by how materials break down, especially glasses and polymers that don't have a regular crystal ...

Hidetoshi Katori and Jun Ye won the 2022 Breakthrough Prize in Fundamental Physics "for outstanding contributions to the invention and development of the optical lattice clock, which enables ...