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 ...

A new derivative of ferrocene has 20 valence electrons, challenging the longstanding rule that organometallic compounds can ...

Researchers at Forschungszentrum Jülich have successfully created the world's first experimentally verified two-dimensional ...

The membrane-bound organelle appears to play a huge role in helping cells sort, discard, and recycle their contents. It's ...

Aqueous zinc-ion batteries (AZIBs) are regarded as a promising next-generation solution for large-scale energy storage due to their advantages such as high safety, low cost, and environmental ...

Researchers are creating new moiré materials at the nanometer scale using advanced DNA nanotechnology. DNA moiré ...

On July 21, 2000, the DONUT collaboration at Fermilab announced the detection of tau neutrinos for the first time. Here are a ...

It is easy to imagine the space between stars and galaxies as a region entirely free of matter, energy, and activity. While ...

Zhuoran Qiao has been awarded the inaugural Chen Institute and Science Prize for Al Accelerated Research for work critical to ...

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

Scientists have discovered a revolutionary new method for creating quantum states by twisting materials at the M-point, revealing exotic phenomena previously out of reach. This new direction ...