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.

Seoul, South Korea - Custics Corporation announced that its proprietary transdermal growth support system Hautuki continues ...

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

Characterization of intracellular synapse heterogeneity aides to understand the intricate computational logic of neuronal circuits. Despite recent advances in connectomics, the spatial patterns of ...

Reference sample designs. In the most widely used experimental design for microarrays, all the direct comparisons are made to a reference sample using the same orientation of dye labeling (Fig. 3 a).

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

Traditional military training often relies on standardized methods, which has limited the provision of optimized training tailored to individual combatants' characteristics or specific combat ...

Her relapse into depression felt like defeat—but it offered vital clues to achieving lasting psychiatric relief. The 67-year-old woman from Alabama had already endured four major depressive episodes ...

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

Genetics research reveals how diverse complex biological systems are. Diversity and collaboration make for more thorough and ...

Weizmann Institute of Science-led researchers have unveiled a computational workflow that crafts enzymes exhibiting catalytic ...