A new web-based tool visualizes catalyst gene profiles, helping scientists explore patterns and improve catalyst design.

By changing the physical structure of gold at the nanoscale, researchers can drastically change how the material interacts with light and, as a result, its electronic and optical properties.

Ultrathin titanium flow distributors made via laser micromachining achieve record fuel cell power densities, surpassing European aerospace targets set for the end of this decade.

Researchers turn discarded cigarette butts into carbon electrodes for supercapacitors, achieving high energy density, fast charging, and long-term stability from toxic waste.

Researchers developed a vortex method to dry non-aggregated cellulose nanofibers from slurry, offering a more efficient, ...

Molecular electronic devices using quantum tunneling could achieve integration densities 1,000 times greater than silicon chips by combining atomic-precision assembly with three-dimensional ...

A novel study demonstrates that droplets at a miniscule level can be precisely controlled, opening new avenues in micro-scale ...

Metasurface converts Gaussian beams to uniform light via polarization encoding, boosting NMR co-magnetometer sensitivity 23% for compact quantum sensors.

Scientists achieve optical measurements at atomic scales using quantum electron tunneling, surpassing conventional microscopy limits by nearly 100,000 times with standard lasers.

A new gas sensor using ruthenium dioxide nanosheets achieves ultra-sensitive ethanol detection down to 5 ppb, enabling real-time breath alcohol monitoring at under 30 milliwatts.