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

Researchers Create New Heavy-Metal Molecule ‘Berkelocene’

Big breakthrough in heavy-element chemistry shatters long-held assumptions about transplutonium elements.

Illustration showing how different molecular surfaces result in pollutants moving through them differently, with a molecular diagram linked to a graph showing different probabilities. There is a series of three pictures above illustrating a farm, a connected power system, and a water filtration system.

Improving Continuum-Scale Models with Molecular-Scale Interface Science

Researchers propose a new approach to modeling adsorption processes that affect how pollutants move through soil, water, and rock.

A huge plume of brown smoke emerging from a volcano

Can AI Anticipate Earthquakes?

Automatic speech recognition predicts earthquake fault displacement.

Improvements to Americium-241 processing can increase yield, decrease the amount of waste generated, and reduce the radiological dose workers receive.

Improving Large-Scale Domestic Production of Americium-241, a Critical Component in Smoke Detectors and Nuclear Batteries

Researchers explore the effects of radiation and harsh chemicals to optimize americium-241 production.

Two synchronized flashes of ultrafast X-rays interact with a molecule. The electrons ionized from the molecule are detected with an energy spectrometer, providing observation of the interaction between the two particles at the attosecond timescale.

Action! Attosecond X-rays Produce Ultrafast Movies

Researchers use an X-ray free-electron laser to film electrons using finely tuned pairs of attosecond flashes.

Conceptual art showing the rare earth element promethium in a vial surrounded by an organic ligand. Scientists have discovered hidden features of promethium, opening a pathway for research on other lanthanide elements.

In an Advance for Promethium Production, Researchers Get a New View of the Element’s Properties

Scientists characterize a promethium coordination complex for the first time, furthering the understanding of difficult-to-study lanthanide elements.

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.

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.

Conversion of CO2 to butene via a solar-driven tandem process. First, CO2 is converted to ethylene using an electrochemical reactor and solar-derived electricity. Next, ethylene is converted to butene via thermal catalysis with heat from solar irradiation.

Driving Chemical Transformations Through the Power of Solar Energy

Researchers combine solar energy, electrochemistry, and thermal catalysis to remove the need for fossil fuel-driven chemical conversions.

A long-predicted ultrafast isomerization in the UV photochemistry of bromoform is visualized for the first time by femtosecond time-resolved electron diffraction. At 267 nm excitation, the reaction pathway surpasses direct dissociation by a 60:40 margin.

Bromoform Molecules Like to Rearrange Their Atoms

Ultrafast electron diffraction imaging reveals atomic rearrangements long suspected to be crucial in the photochemistry of bromoform.

Researchers retrieved the time-varying molecular structure of photoexcited o-nitrophenol from ultrafast electron diffraction data using a genetic algorithm

Speedy Nuclei Do the Twist

Ultrafast electron imaging captures never-before-seen nuclear motions in hydrocarbon molecules excited by light.