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

A guide RNA strand, in purple, guides CRISPR to a DNA strand. Scientists devised a method to identify genes that can be suppressed to customize microbes for biotechnology applications.

Investigating Cyanobacteria’s Many Paths to Adaptation

A new approach accelerates how quickly scientists can identify genes involved in environmental acclimation and understand bacterial stress.

A group of researchers in a laboratory, with four men standing up and a man and woman sitting down

Robotic Lab Revolutionizes Plant Bioengineering

A fast, automated, and high-throughput pipeline is improving the speed of plant engineering

Series of five different line graphs indicating how the code matched the experimental data fairly well

Improving Predictions for Fusion Device Transport

Researchers validate a new workflow for plasma transport models, aiding future fusion device design.

An illustration with blue pairs of electrons on the left against a teal background and pink pairs of electrons on the right against a pink background with a honeycomb layer between them

Can a Superconductor Also Be a Magnet?

Special graphite flakes are defying conventional thought in physics by showing that a material can be a superconductor and a magnet at the same time.

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.

Graph comparing a neutron star with a quark-matter core vs. a nuclear matter core in mass vs. radius. The quark matter core star would have less mass and radius than the nuclear matter core, as stars with smaller radii and more mass are too unstable.

New Clues on Twin Neutron Stars and the Extreme Physics Inside

Scientists have new insights into factors that determine how twin neutron stars—stars with the same mass but different sizes and compositions—can coexist.

Microscopy image with a zoom-in to show the layers of different substances, as well as a graph showing resistivity changes substantially depending on temperature.

Harnessing Entangled Spin Fluctuations for Advanced Spin Electronics

The spin fluctuations of an insulating quantum magnet determine how electricity flows in a nearby metal film.

Illustration showing a crystal structure, with balls connected by lines and a blue ball increasing in size moving above the structure

Thin Materials and Fat Electrons: A Recipe for New Quantum Phenomena

The 2D material cerium silicon iodide contains the same heavy electrons responsible for heavy fermion physics, something so far seen only in 3D materials.

Graphic showing how a thin film can go through compressive strain on top of a substrate to become superconducting as well as a line graph showing how the most strain induces superconductivity

Unveiling the Link Between High Pressure and Superconductivity

Researchers have learned how to retain superconductivity at ambient pressure in a new class of high temperature superconductors.

Illustration of alpha fusion processes in stars and reactions used on Earth floating above an image of the Earth

Predictive Theory Revises Understanding of Alpha Processes During the Big Bang and in Massive Stars

Theoretical calculations enable more accurate determination of reaction rates for modelling primordial lithium-6 abundance and massive stars’ lifecycle.

An interaction that governs triton decay (left) is also critical to proton-proton fusion (right). Extracting information from the well-measured triton decay provides a prediction for the rate of proton-proton fusion.

Understanding How the Sun Shines: From Triton Decay to Proton-Proton Fusion

Remarkably, the rate of proton-proton fusion in the sun is not precisely understood, but it can be better predicted using the process of triton decay.

Steps in terbium-161 (Tb-161) production. The University of Utah TRIGA reactor induces thermal neutron capture on gadolinium-160 (Gd-160), which decays to Tb-161. Separating the Gd-160 target yields high-purity Tb-161 for cancer therapy and diagnosis.

To Advance Cancer Therapy, University Starts Producing Terbium-161

A University of Utah research team demonstrates that a low power university research reactor can produce terbium-161 at high purity from gadolinium-160.