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

A depiction of how equilibrium is maintained in hadrons. Pressure from quarks and gluons (outward-pointing purple arrows) balances against pressure from trace anomaly and sigma terms (inward-pointing blue arrows).

Scientists Discover Energy and Pressure Analogies Linking Hadrons, Superconductors, and Cosmic Expansion

From the microscopic world to the entire Universe, pressure and energy relate in a similar manner.

Top: the time evolution of a typical collision of oxygen and carbon nuclei and the shapes of the fused system. Bottom: experimental fusion probability compared to the results of thousands of simulations (black line) for a large range of energies.

Researchers Directly Simulate the Fusion of Oxygen and Carbon Nuclei

A significantly improved description of experimental results suggests the importance of presently unaccounted for phenomena in fusion.

(a) The moment of inertia is smaller for prolate shapes and larger for oblate shapes. (b) Nuclei combine several such shapes. (c) A snapshot of the neon-20 nucleus from simulations. Studying the shape can help explain the physics of fast-rotating nuclei.

Resolved: A Long-Debated Anomaly in How Nuclei Spin

Scientists resolve the hypothesized anomalous increase in moment of inertia of fast rotating nuclei with models of neon-20 and chromium-48 nuclei.

Quark recombination in the quark-gluon plasma formed in high-energy nuclei collisions enhances the production of Bc mesons. These mesons consist of a charm quark and a bottom quark. Most of the quark-gluon plasma decays into thousands of other particles.

Scientists Study How B_c Mesons Form to Gain More Information from Ultra-Relativistic Heavy-Ion Collisions

Evidence for the formation of a quark-gluon plasma emerges from the recombination of freely moving charm and bottom quarks into B_c mesons.

Illustration of a proton-proton collision at the Large Hadron Collider. Quarks produced in these collisions can cluster in threes to produce baryons (green) or in twos to make mesons (red).

Research Offers New Insights into the Mechanisms of How Quarks Combine

Measurements from the LHCb collaboration expand scientific understanding of how individual quarks assemble to form observable matter.

Physicists modeled gold-gold collisions at different energies to probe fluid properties over a range of temperatures and baryon densities. The dashed line represents the region where ordinary nuclear matter is expected to transition to free quarks and gluons.

How Sticky Is Dense Nuclear Matter?

Scientists use a large-scale statistical analysis to extract the viscosity of hot, dense nuclear matter created at different heavy ion collision energies.

Hubble Space Telescope image of the globular cluster NGC 2419, a collection of stars orbiting the Milky Way about 300,000 light years away from Earth.

New Experimental Results Set the Stage for Understanding the Mysterious History of NGC 2419

High resolution study of calcium-40 Ca to constrain potassium nucleosynthesis in the NGC 2419 globular cluster.

Shaded outlines of calcium-40 and ytterbium-176 nuclei (40Ca+176Yb) as they collide, leading to fusion, with nucleon currents for neutrons in blue and protons in red. The net neutron flow is from 176Yb to 40Ca and the proton flow is the opposite.

New Insights on the Role of Nucleon Exchange in Nuclear Fusion

Researchers expand the quantum mechanical descriptions of nuclear fusion reactions.

Novel Hybrid Scheme Speeds the Way to Simulating Nuclear Reactions on Quantum Computers

Classical and quantum chips combine to simulate the collision of two neutrons on a present-day quantum computer.

Collisions of heavy ions generate an immensely strong magnetic field that in turn induces electromagnetic effects in the quark-gluon plasma, a “soup” of quarks and gluons liberated from the colliding protons and neutrons.

STAR Sees a Magnetic Imprint on Deconfined Nuclear Matter

Data from heavy ion collisions give new insight into the electromagnetic properties of quark-gluon plasma “deconfined” from protons and neutrons.

Using lasers with precisely tuned frequency, λ, physicists control rotational states of radium monofluoride molecules and excite specific rotational levels, characterized by the quantum number, J. These excitations manifest as sharp spectral peaks.

Precision Measurements of Radioactive Molecules for Fundamental Physics

Pushing boundaries with radioactive molecules for future studies of nuclear structure and fundamental symmetry.

Final assembly of germanium radiation detectors for the MAJORANA DEMONSTRATOR in 2015. These detectors produced a low-background, “quiet” data set that researchers used to search for signs of dark matter and other physics beyond the Standard Model.

Expanding the Hunt for Hidden Dark Matter Particles

Researchers dramatically improve the limits for several exotic dark matter models.