Quantum physics is no longer confined to cryogenic chips and vacuum chambers. It is starting to seep into the machinery of ...

The so-called magneto-sensitive fluorescent proteins or MFPs, overcome key limitations of previous biological candidates for quantum sensors.

A team of researchers from the University of Chicago's Pritzker School of Molecular Engineering (UChicago PME) has used ...

A team at Japan's National Institutes for Quantum Science and Technology (QST) has published a field-defining Perspective ...

Diamond nanoparticles containing nitrogen-vacancy centers can now monitor cellular metabolism in real time, targeting specific organelles while tracking particle movement inside living cells.

Protons, the positively charged particles that help build every atom in our bodies, are starting to look less like classical billiard balls and more like quantum actors. A growing body of research now ...

Quantum sensors made from a glowing protein can be produced by living cells and could be used to much more accurately measure tiny changes in the body. This could one day help with early disease ...

Atomic defects in nanodiamonds enable both precise heating of lysosomes inside macrophages and nanoscale temperature measurement, revealing that localized thermal spikes trigger immune cell ...

Quantum dot solar cells harness the unique properties of semiconductor nanocrystals to capture a broader spectrum of solar radiation, offering substantial promise for next-generation photovoltaics. By ...

Ischemic stroke remains a leading global cause of disability and mortality, and a major challenge in stroke treatment is "reperfusion injury"—where return of blood flow causes oxidative stress and ...

Universal Quantum has staked its reputation on the trapped-ion approach, allowing it to scale in the quickest and most ...