Johns Hopkins researchers have discovered new materials and a new process that could advance the ever-escalating quest to make smaller, faster, and affordable microchips used across modern electronics ...

One of the key steps in developing new materials is property identification, which has long relied on massive amounts of experimental data and expensive equipment, limiting research efficiency. A ...

Scientists are learning how to temporarily reshape materials by nudging their internal quantum rhythms instead of blasting them with extreme lasers. By harnessing excitons, short-lived energy pairs ...

Responsive materials that morph and adapt like biological systems are non-trivial to design and manufacture. Researchers developed a co-design framework that unites AI, physics, and 3D printing into ...

Machine-learning models can speed up the discovery of new materials by making predictions and suggesting experiments. But most models today only consider a few specific types of data or variables.

Molecule-based magnets like vanadium tetracyanoethylene are extremely sensitive to air, impeding their use in practical quantum devices. Researchers coated vanadium tetracyanoethylene with an ...

Revisiting well-known semiconductors, engineers have produced a low-cost approach to infrared emitters and sensors with potential environmental, medical, and industrial applications.