Discovered: Tiny Drops of “Perfect” Fluid that Existed in the Early Universe
Particles colliding at nearly light speed reveal information about the true nature of matter.
Particles colliding at nearly light speed reveal information about the true nature of matter.
Upgraded capabilities ready to explore quarks and gluons ready at the Large Hadron Collider.
Scientists shed new light on a proton's spin, refining our understanding of nuclear physics.
First description of common particle’s properties provides insights into the nature of the universe.
New research could change our view of neutron stars and other systems with neutron-rich nuclei.
New detector component picks up particles composed of heavy quarks to probe primordial quark-gluon plasma.
Researchers count the number of radioactive krypton-81 atoms remaining in ice using a laser trap.
The recently upgraded CEBAF accelerator delivers its highest-energy electron beams into a new experimental complex for the first time.
An optimized nuclear force model yields a high-precision interaction with an unexpected descriptive power.
Scientists make the first experimental determination of the weak charge of the proton and extract the weak charges of the neutron and up and down quarks.
Advances in theory have made it possible to predict cooling behavior observed in accreting neutron stars.
Argonne superconducting radiofrequency technology boosts a variety of applications.
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