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.

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

In “ Natural History ,” your story in this week’s issue, Jesse joins an environmental protest, a kind of die-in, at the ...

For thousands of years, humans have combined metals to collectively harness properties found in individual components, ...

Researchers have found the first new type of magnet in nearly a century. Now, these strange "altermagnets" could help us ...

During times of uncertainty, ikigai provides stability and guidance, serving as a compass with four points, which directs us ...

Mercedes-AMG G63 is still one of the meanest, coolest, luxurious, excessive and most striking automotive icons still in ...

The 'Tree of Robots' from the Technical University of Munich classifies robots by sensitivity, aiming for a new safety and ...

A Department of Homeland Security memo from June, describing the Pentagon’s findings, said that the group, publicly known by ...

It took until the last room of her exhibition for me to gain any real understanding of the work of Australian Aboriginal ...

Learn about Richard Feynman, the Nobel Prize-winning physicist known for quantum electrodynamics, his unique teaching style, ...

If the receiver of an anonymous message is taken to be the adversary, then their best guess from a set of candidate senders ...