Science Highlights | U.S. DOE Office of Science (SC)

Experimental turbulence model matches the magnetic field amplification seen within the remains of a supernova.

Realistic computational view of how atom stretches informs microscopic description of nuclear energy production.

Particles colliding at nearly light speed reveal information about the true nature of matter.

The proton's primary building blocks, up and down quarks, are produced more often than strange quarks in scattering experiments.

Researchers determine the reaction pathway to how soot and other toxic components form in combustion systems.

Pairs of precisely tuned X-ray pulses uncover ultrafast processes and previously unmapped structures.

Careful tuning of a surface at the nanoscale could lead to robust materials for solar panels, other uses.

Atomic-scale defects in graphene are shown to selectively allow protons to pass through a barrier that is just one carbon atom thick.

Computational algorithms show whirlpools, not disks, form and dissipate on fluid’s surface.

New models reveal the impact of competing processes on helium bubble formation in plasma-exposed tungsten.

Lead and bismuth systems are being produced to fill the nation’s need for short-lived, alpha-emitting isotopes.

New structures could accelerate progress toward faster computing and high-security data transfer across fiber optic networks.