A new modeling framework helps understand the consequences of future sea-ice loss in the Arctic.
The mechanism responsible for creating intense magnetic fields in laser-driven plasmas also helps tear the fields apart.
Unexpected molecular interactions involving water clusters have a subtle, yet profound, effect on extractants picking their targets.
Comparing new prediction to measurements of muons’ precession could potentially help scientists discover new subatomic particles.
Crests of watery waves breaking in oil may be the gatekeepers to transport vital chemicals in industrial separation process.
Researchers developed a new self-generating lubricant with great potential for industrial applications.
Charged particles emanating from Jupiter’s magnetosphere are powered up to create the northern and southern lights on Ganymede, Jupiter’s largest moon.
Collaboration powers machine learning software that performs data analytics on petabyte-sized data sets in series of successful test runs.
Systems biology leads the way to exascale computing on Summit supercomputer.
The first-ever computation of an atomic nucleus, the deuteron, on a quantum chip demonstrates that even today’s rudimentary quantum computers can solve nuclear physics questions.
Supercomputer simulations and theoretical analysis shed new light on when and how fast reconnection occurs.
A nickelate thin film senses electric field changes analogous to the electroreception sensing organ in sharks, which detects the bioelectric fields of prey.
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