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

An artist’s impression of a quantum electrodynamics simulation using 100 qubits of an IBM quantum computer. The spheres and lines denote the qubits and connectivity of the IBM quantum processor; gold spheres denote the qubits used in the simulation.

Nuclear Physicists Create Scalable Quantum Circuits to Simulate Fundamental Physics

Researchers developed and executed algorithms for preparing the quantum vacuum and hadrons on more than 100 qubits of IBM quantum computers.

A photon (γ) and a jet of other particles emerges from a proton-proton (p-p) collision (left). But in a deuteron (d)-gold nucleus (Au) collision (right), the jet loses energy while the photon is not affected. Neutral pions (π0) are proxies for the jet.

Fresh Direct Evidence for Tiny Drops of Quark-Gluon Plasma

Particles of light from collisions of deuterons with gold ions provide direct evidence that energetic jets get stuck.

An artist’s impression of an analog quantum computer in which atoms are manipulated by lasers to simulate quantum many-body systems.

Scientists Take an Important Step toward Mitigating Errors in Analog Quantum Simulations of Many-Body Problems

A new framework for quantifying uncertainties increases the predictive power of analog quantum simulations.

Strong interactions between neighboring metal and sulfur atoms are found to influence the properties of electronic excited states created by light absorption, as shown by X-ray spectroscopy methods at the Stanford Synchrotron Radiation Lightsource.

Excited Electronic States of Metallic Atoms Rely on their Sulfuric Neighbors

Scientists discover that bond covalency is an important property of excited states in molecules containing metal-sulfur bonds.

Crystallographic and spectroscopic evidence now show that americium and curium yield a variety of polyoxometalate compounds that their lanthanide counterparts are unable to form.

Heavy Ligands Unravel New Chemistry for Heavy Elements

Heavy ligands, like polyoxometalates, open a new frontier in the chemistry of actinide elements.

Illustration of quarkonium states interacting with co-moving particles in relativistic heavy ion collisions.

Scientists Measure the Temperature Achieved in Heavy Ion Collisions by Looking at Broken Particles

First precise measurement of a hard to detect bound charm quark pair state indicates it is not affected by the medium in high-energy proton-lead collisions.

Simulated predicted shape distribution for magic-sized silver clusters (purple insets) assembled at different solvent temperatures. These predictions can guide experiments to target seeds for crystal growth.

Molecular Modeling Reveals How Nanocrystals Take Shape

The shape of tiny silver seeds made of fewer than 200 atoms depends on their precise size and temperature and defines the shape of the final nanoparticle.

In a strange metal (translucent box), electrons (blue marbles) lose their individuality and melt into a featureless, liquid-like stream.

Can Electricity Flow Without Electrons?

Strange metals defy the 60-year-old understanding of electric current as a flow of discrete charges.

A cartoon of robot-enabled inorganic materials synthesis. The robot selects powder precursors based on new criteria, mixes them by ball milling, moves them to an oven, and measures the results with X-ray diffraction to determine the phase purity.

New Approach to Materials Synthesis—with Quick Validation by a Robotic Lab

Inorganic precursors chosen based on new criteria led to higher phase purity for 32 out of 35 target materials synthesized in a robotic laboratory.

Dilution refrigerators keep superconducting qubits cold.

When to Go Multinode? A Novel Approach Aids Quantum Computer Designers

Researchers use a co-design approach to quantify performance tradeoffs in multinode superconducting quantum computers.

Illustration of an idealized extraction chromatographic resin using DGA or LN extractants. By studying the adsorption properties of terbium on these DGA and LN resins, scientists gain insights into these properties for the entire lanthanide series.

Understanding the Adsorption Properties of Terbium for Future Medical Use

Scientists investigate the adsorption, thermodynamics, and kinetic properties of terbium on two popular resins for lanthanide separations: DGA and LN.

Structure of Iridium (Ir) dimer complex showing an Ir-Ir bonding molecular orbital populated (left) and an Ir-Ir anti-bonding molecular orbital depopulated (right) by optical excitation.

Advanced Techniques Paint a More Accurate Picture of Molecular Geometry in Metal Complexes

Ultrafast X-ray scattering and advanced numerical simulations decode distinct molecular structures and their equilibration dynamics in metal-metal complexes.