Physicists show that black holes and dense state of gluons—the “glue” particles that hold nuclear matter together—share common features.
Experiment shows that even large, old, and presumably stable stores of soil carbon are vulnerable to warming and could amplify climate change.
Powerful statistical tools, simulations, and supercomputers explore a billion different nuclear forces and predict properties of the very-heavy lead-208 nucleus.
Nuclear physicists test whether next generation artificial intelligence and machine learning tools can process experimental data in real time.
Scientists analyzed detonation formation in hydrogen/methane air mixtures, quantifying the effect of non-thermal reactions on the mechanism of detonation.
Using a novel combination of advanced research techniques, scientists show how the roots of various tropical plants react to harsh conditions.
Nuclear physicists find that the internal structures of protons and neutrons may be altered in different ways inside nuclei.
Quantum technique accelerates identification of entangled materials.
Combining synthesis, characterization, and theory confirmed the exotic properties and structure of a new intrinsic ferromagnetic topological material.
The results may offer insight into the quark-gluon plasma—the hot mix of fundamental nuclear-matter building blocks that filled the early universe.
Studies of the nanostructure of a chiral magnet provides insights on controlling magnetic properties for applications in computers and other electronics.
Neutron scattering monitors structures during post-production heat treatment to validate production models.
