Reaching Back Towards the Big Bang
US-led experiments at the LHC recreate the brightest, most dense quark gluon plasma.
US-led experiments at the LHC recreate the brightest, most dense quark gluon plasma.
Particles flowing from heavy ion collisions at RHIC and LHC reveal properties of new form of matter.
Argonne’s new superconducting cryomodule enhances its ATLAS heavy-ion accelerator.
First measurements of isotopes produced by Argonne’s new CARIBU facility provide insight into the creation of the elements in the universe.
Novel high temperature superconductor magnet technology charts new territory.
Surprisingly large effect greatly increases the probability that new neutrino experiments will be able to see the differences between matter and antimatter.
The optimization of commercial hardware and specialized software enables cost-effective supercomputing.
Gamma-ray detectors built with silicon photomultiplier arrays provide high-resolution 3D imaging for research.
Thomas Jefferson Laboratory lends expertise in cryogenics developments.
Discovery could provide a deeper understanding of the dynamics of the three quarks enslaved inside the nucleon.
Precision analytical techniques developed for fundamental experiments in nuclear physics now enable routine measurements of ultra-low concentrations of Krypton radioisotopes in samples of water, ice, and gas.
Imaging tools aid research in global climate change, plant genetics, biofuels, agriculture, and carbon sequestration.
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