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

Photograph of an optically trapped microparticle in high vacuum. The microparticle is visible as a white dot levitated between two lenses, which are used to focus and collect the invisible infrared laser light used to trap the particle.

Detecting the “Kick” from a Single Nuclear Decay

Scientists have detected nuclear decay by observing the recoil of a dust-sized particle when a single nucleus within it decays.

Two examples of silicon photoelectrodes. Left: Micropillar silicon with cobalt catalysts reduces carbon dioxide (CO2) to methanol (CH3OH). Right: Porous silicon with rhenium catalysts reduces carbon dioxide (CO2) to carbon monoxide (CO).

For Solar Fuels, More Surface Area on Photoelectrodes Makes a Difference

High-surface area silicon improves light-driven reactions of carbon dioxide.

Scanning tunneling microscope map of a device made of three atomic layers of graphene. The contrast reveals the wavefunction of a chiral interface state (bright stripe) between two insulating regions having opposite chirality (dark color sides).

Chiral Asymmetry Creates a Path to High-Efficiency Future Electronics

Scientists learn how to manipulate quantum properties in graphene to create resistance-free, electricity channels for loss-free future electronics.

This image shows (a) the Nature magazine cover; (b) the single atom X-ray mechanism; (c) a supramolecular ring with one iron atom; (d) X-ray spectra of one iron atom; (e) a terbium dimer complex; (f) the X-ray spectra of one terbium atom.

For the First Time, Scientists X-Ray a Single Atom

Synchrotron X-ray spectroscopy allows atom-level examination of iron and terbium atoms.

Color map of the differential conductance as a function of increasing magnetic field (x axis) in niobium deposited on 2D molybdenum ditelluride (MoTe2). The red spikes are oscillations of the MoTe2 edge supercurrent due to magnetic field flux.

Superconductivity Is Unpredictable at the Edge

Two types of superconductivity compete at the edge between a topological semimetal and a conventional metal, causing the electrons to switch behavior erratically.

Artist’s representation of gene expression in mycorrhizae-colonized roots as obtained by the combination of single-cell and spatial gene expression analyses.

Researchers Use a New Two-Dimensional Analysis to Build a Map of Gene Expression in Plant-Fungi Interactions

Spatial transcriptomics, combined with single-cell expression profiling, reveals new information on plant/arbuscular mycorrhizal interactions.

Shale is physically and chemically complex at all scales of interest. Multimodal, multiscale imaging, and characterization allows researchers to study how to control the transport and reactivity of matter inside complex porous structures such as shale.

Scientists Characterize Shale Cap Rocks at Tiny Scales

Years of basic scientific research crosscutting multiple disciplines produces new information on the nanoscale complexities of shale.

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.

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.

Artist’s depiction of the spray of particles arising from the collision of two heavy atoms. As the hot subatomic soup cools, newly formed particles shower off into space.

Discovery Sheds Light on the Origins of Matter in the Early Universe

A new calculation helps scientists understand how matter formed out of the hot, dense soup of subatomic particles created by the Big Bang.

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.

False color plot showing the density of the mass in the equatorial (bottom) and meridional, or “southern” (top) planes of a neutron star merger remnant about 100 milliseconds after the merger.

What Happens to the Remains of Neutron Star Mergers?

Simulations of massive neutron star merger remnants reveal their structure and early evolution as they cool down by emitting neutrinos.