Scientists achieve groundbreaking room-temperature quantum coherence for 100 nanoseconds, propelling molecular qubits closer to practical quantum computing.

Scientists achieve groundbreaking room-temperature quantum coherence for 100 nanoseconds, propelling molecular qubits closer to practical quantum computing.
Massive neutron stars have such enormous pressure in their cores that neutrons residing there lose their integrity and become a new type of matter.
A light-matter hybrid material on attosecond scales showcases enhanced conductivity with potential applications in solar cells and high-power electronics.
Scientists uncover a surprising link between hyperbolic metamaterials and gravity, revealing that light behaves similarly in both realms.
Even a well-established theory like the Standard Model is not accurate all the time, and there are phenomena that defy its predictions.
Scientists achieve a decade-long goal, perfecting the combination of attosecond pulses of light with electron microscopy to study matter.
Scientists propose an enhancement to the BabyIAXO axion detector, paving the way for an intensified search for elusive dark matter particles.
A newly discovered material and its intriguing properties could pave the way for more efficient computing.
The math of multi-particle entangled systems is fiendishly complex, but researchers have made a step forward.
Physicists working on LIGO have surpassed the quantum limit to enhance gravitational wave detectors and revolutionize astrophysical observations.