Researchers led by Genki Kobayashi at the RIKEN Pioneering Research Institute (PRI) in Japan have discovered a way to max out ...

Researchers unveil a chemistry playbook to turn stubborn MAX phases into tunable 2D materials, blending MXene and ...

A research team led by Prof. Huang Qing from the Ningbo Institute of Materials Technology and Engineering (NIMTE) of the ...

To visualize a time crystal, think of Earth looping back to its same location in space every 365¼ days; the planet repeats itself periodically as it moves through time.

The fundamental challenge has been that creating photonic time crystals required materials to change their optical properties by nearly 100% – a feat that would demand enormous amounts of energy.

Time crystals form a repeating pattern by "flipping" between two atomic states precisely on the clock. Those properties could be useful for silicon chips, fiber optics, and much more.

Scientists from the Interface Science Department at the Fritz Haber Institute have studied how applying pulsed electric ...

Physicists in Finland are the latest scientists to create “time crystals,” a newly discovered phase of matter that exists only at tiny atomic scales and extremely low temperatures but also ...

The new results indicate that beams of ionic crystals should be possible to maintain even in large, high-energy ion accelerators, as long as the beam trajectories are smooth.