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.

Caltech scientists have found a fast and efficient way to add up large numbers of Feynman diagrams, the simple drawings ...

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

In a paper published in Nature Physics, the Caltech team uses its new method to precisely compute the strength of ...

Caltech scientists have found a fast and efficient way to add up large numbers of Feynman diagrams, the simple drawings physicists use to represent ...

A research team in South Korea has developed a cutting-edge catalytic and separation process that enables the simultaneous ...

Professor Xiao-Gang He and Dr. Chia-Wei Liu of Shanghai Jiao Tong University's Tsung-Dao Lee Institute (TDLI) used the ...

Neurovascular variations are highly prevalent, encompassing differences in origin, course, and vascular territories, which may result in atypical clinical ...

If you pull twice as hard on a spring, it stretches twice as far. However, when we introduce very large forces or complicated ...

Experiments show that carbon nanotubes transfer heat inefficiently at small scales, raising concerns for cooling and ...

Recently, a research team at the Hefei Institutes of Physical Science of the Chinese Academy of Sciences (CAS) proposed a novel model optimization algorithm named External Calibration-Assisted ...