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

For the first time, researchers simultaneously achieved density above a historical empirical limit (>1.0) and very good confinement (~1.5) in a tokamak device.

Ground-Breaking Efforts Overcome an Operational Limit of Tokamaks, Advancing Efforts to Achieve Fusion Energy

By achieving very high density and confinement quality at the same time, researchers make new strides toward fusion energy.

This research studied the reduction of carbon monoxide to methanol using ruthenium complexes. Information about the ruthenium came from data collected at the National Synchrotron Light Source II.

An Improved Domino Chain for Sustainable Methanol Synthesis

Scientists used a series of three distinct, sequential reactions to transform carbon monoxide into methanol using proton-electron mediators.

Researchers combined high magnetic fields with X-ray scattering to reveal the connection between superconducting vortices (black circles), charge density waves (red wiggles), and spin density waves (blue wiggles) in a cuprate superconductor.

What Makes High Temperature Superconductivity Possible? Researchers Get Closer to a Unified Theory

Scientists discover that superconductivity in copper-based materials is linked with fluctuations of ordered electric charge and mobility of vortex matter.

Nanocrystals (left) capture light (hv) and then transfer electrons (e-) to nitrogenase enzymes (upper right) to convert dinitrogen (N2) to ammonia (NH3). A sacrificial reaction (bottom right) completes the process.

Powering Enzymes with Light to Make Ammonia

Scientists examine how molecular systems made of nanocrystals and proteins support the production of ammonia using light.

Charge radii differences in mirror nuclei, which have opposite numbers of protons and neutrons, can help constrain parameters for the equation of state nuclear matter, which describes the properties of astrophysical objects such as neutron stars.

“Mirror” Nuclei Help Connect Nuclear Theory and Neutron Stars

Charge radii measurements of silicon isotopes test nuclear theories and guide descriptions of nuclear matter.

Neutrinos of different “flavor” quantum states (shown by colors) are entangled through interactions. In dense neutrino environments like core-collapse supernovae, this leads neutrinos of different flavors to equilibrate to similar energy distributions.

In Neutrinos, Quantum Entanglement Leads to Shared Flavor

Researchers find that the quantum flavor and momentum states of the neutrinos in a supernova are strongly entangled through frequent interactions.

Abstract representation of subcooled flow boiling modeled on experimental data collected for the Los Alamos National Laboratory Isotope Production Facility.

Deep Learning Model Overcomes the Challenge of Real-World Measurements of Isotope Production Target Cooling Systems

Researchers develop a framework to predict subcooled flow boiling and critical heat flux.

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.