Electrons can be elusive, but Cornell researchers using a new computational method can now account for where they go—or don't ...

A new atomically precise carbon sheet combines nanoporous graphene and biphenylene stripes, offering controlled ...

Highspeed Internet, autonomous driving, the Internet of Things: data streams are proliferating at enormous speed. But classic ...

Quantum physics is usually associated with particle colliders and vacuum chambers, not with the proteins quietly shuttling ...

Researchers engineered a strained germanium layer on silicon that allows charge to move faster than in any silicon-compatible ...

Highspeed Internet, autonomous driving, the Internet of Things: data streams are proliferating at enormous speed. But classic radio technology is reaching its limits: the higher the data rate, the ...

Topological materials promise electronics that are faster, cooler, and far more robust, but until now they have mostly ...

Think of the IBM Quantum Experience as your personal key to unlock these super-powered quantum computers. It’s a website ...

Acoustic waves are best known as the invisible delivery agents bringing voices, car horns, or our favorite song to our ears. But the waves can also move physical objects, like an item vibrating atop a ...

Iron-on patches can repair clothing or add personal flair to backpacks and hats. And now they could power wearable tech, too.

Researchers have combined liquid metal and a heat-activated adhesive to create an electrically conductive patch that bonds to ...

An international collaboration led by Cornell University researchers used a combination of psilocybin and the rabies virus to ...