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Nuclear and Chemical Sciences

Lawrence Livermore National Laboratory’s Forensic Science Center created a novel technique to uncover traces of the Soman nerve agent, strengthening chemical forensics and OPCW investigations. FSC team left to right: Adele Panasci-Nott, Alexander Vu, Carlos Valdez, Mark Dreyer, David Cho, David Baliu-Rodriguez and Saphon Hok (Photography: Blaise Douros)

LLNL’s Forensic Science Center develops a new capability to detect chemical weapons

In the aftermath of suspected chemical attacks, investigators from the Organization for the Prohibition of Chemical Weapons (OPCW) step in to collect chemical, environmental and biomedical samples. Thorough forensic laboratory analysis of these samples is essential for proving what — if any — chemical agents were used and verifying their identities. Researchers at Lawrence…

In the latest episode of the Big Ideas Lab, discover how LLNL researchers prepared and analyzed samples retrieved from the asteroid Bennu. (Photo: Garry McLeod/LLNL)

Analyze an asteroid sample in the latest episode of the Big Ideas Lab

In the early 2000s, a team of planetary scientists at NASA began planning something audacious. They would build a spacecraft. Aim it at an asteroid. Launch it across more than a billion miles of space. Map the asteroid’s rugged terrain at an unprecedented, centimeter-level resolution. Hover over the surface to collect a sample. And then bring it all the way home. The…

As hydrogen reacts with uranium, it creates blisters (a) that burst (b) and release uranium hydride powder. The interaction results in surface degradation (c) that can impact material safety and lifetime.

Roll the tape: LLNL captures inception of hydrogen-uranium reaction for the first time

When hydrogen gas interacts with uranium metal, the combination creates a chemically reactive powder and a runaway reaction that is difficult to stop. The result can impact the safety and lifespan of technology critical for fusion energy, hydrogen storage and nuclear fuels. In a recent study published in npj Materials Degradation, researchers from Lawrence Livermore…

A diagram of the plasma flow reactor that can be used to examine particles as they move from a hot plasma (left) to a cooler condensed state (right). (Courtesy image)

LLNL scientists use controlled experiments to better understand nuclear fallout

In less than a millionth of a second after a nuclear detonation or a severe nuclear reactor accident, an enormous burst of energy heats the surrounding air and materials. Everything in the vicinity is vaporized into a hot, glowing cloud of gas and plasma. As that nuclear fireball expands, it mixes with air, begins to cool and condenses into tiny solid particles — creating…

The AVLIS program began at LLNL in 1973 and was suspended in 1999. Now, the technology is being revived to create a domestic process for enriching lithium and fuel an energy-resilient nation.

Revitalized laser technology captures commercialization grant

Small, modular nuclear fission reactors and fusion facilities could each be the future of resilient and secure energy in the U.S. and around the world. But these technologies rely on isotopes of lithium to cool fission reactors and create fusion fuel. Currently, there is no sustained, domestic production mechanism for lithium isotopes in the U.S. that meets projected…

Audience view of the stage, where a presenter shows a 4-panel cartoon about a stardust grain forming in a star, then traveling through space, final panel depicts scientist with a telescope.

‘Science on Saturday’ lecture brings students along a cosmic treasure hunt to find stardust in meteorites

Lawrence Livermore National Laboratory’s (LLNL’s) educational outreach program Science on Saturday kicked off its 2026 program with an impactful lecture on meteorites and cosmochemistry. Held on Saturday mornings at the Mertes Center for the Arts in Las Positas College, the annual series offers local students and other community members a glimpse into the life and work of…

Lawrence Livermore National Laboratory has announced five research teams selected for awards through the Lab’s FY26 Academic Collaboration Team annual call for proposals.

Weapons Physics & Design ACT awards drive university partnerships and research

Lawrence Livermore National Laboratory (LLNL) has announced five research teams selected for awards through the Lab’s FY26 Academic Collaboration Team (ACT) annual call for proposals. Awards support university research partners for up to three years to perform research in collaboration with Lab scientists and offer an important way to build long-term connections with…

Wyatt Larrinaga studies how proteins bind to radioactive elements during a graduate student fellowship at LLNL. (Graphic: Dan Herchek and Jeremy Gardner / LLNL)

Grad student Wyatt Larrinaga explores how proteins bind to radioactive elements for fellowship at LLNL

As a fifth-year graduate student at the Pennsylvania State University, Wyatt Larrinaga investigates how proteins can be used to separate lanthanides. These elements, plus two others, make up the rare earth elements that are critical for technology, defense and a robust domestic energy supply. But somewhere along the way, Larrinaga grew interested in branching out. Or,…

Artist’s depiction of NASA’s Dragonfly rotorcraft exploring the icy, hydrocarbon-rich landscapes of Titan, Saturn’s largest moon. (Courtesy image: NASA/Johns Hopkins APL/Steve Gribben)

LLNL delivers advanced gamma-ray spectrometer for NASA’s Dragonfly mission to explore Titan

Hundreds of millions of miles away from Earth, the landscape of Titan, Saturn’s largest moon, bears a striking resemblance to our own planet — but with dunes of hydrocarbon sands rather than silica sands, and rain, rivers, lakes and seas of liquid methane and ethane rather than liquid water. The NASA Dragonfly mission is set to explore this world in unprecedented detail…

The magnetic microcalorimetry team operates a dilution refrigerator used for ultra-sensitive magnetic microcalorimetry. Their work enables the precise measurement of nuclear decay events at extremely low temperatures. From left to right: Inwook Kim, Chang Lee, Geon-Bo Kim (corresponding author), Ryan Wood (first author) and Nathan Hines.

Cryogenic micro-calorimetry offers a novel material-dating method for nuclear forensics and safeguards

The moment nuclear material is produced, processed or purified, it sets off a hidden countdown, marked by the half-life of its radioactive atoms as they begin to decay. For scientists tracking the origins of these substances, decoding this natural clock is crucial for verifying material histories in support of global security efforts. In a new study published in the…

The 2026 DMTS cohort is pictured here

LLNL honors 36 as 2026 Distinguished Members of Technical Staff

Thirty-six Lawrence Livermore National Laboratory (LLNL) researchers have been named Distinguished Members of Technical Staff (DMTS) in recognition of their extraordinary scientific and technical contributions, as affirmed by their professional peers and the broader scientific community. As distinguished citizens of the Laboratory and their respective fields, DMTS honorees…

Plot illustrating a direction-finding algorithm.

Novel directionality algorithm from student-led team selected as featured journal article

Many areas of science and engineering face the same challenge: how to infer a preferred direction when the information is spread across many measurements rather than appearing as a single clear feature. This arises in particle physics and astronomy, as well as in imaging and machine learning, whenever data take the form of a two-dimensional grid, or histogram. A student…

LLNL researchers have successfully synthesized a californium compound using polyoxometalates — large, cage-like clusters made primarily of metal and oxygen atoms. Their research was featured on a journal cover for Chemical Communications.

Americium, curium and californium — oh my! Crystallizing the rarest elements at LLNL

Actinides are a group of heavy, radioactive elements that include uranium, plutonium, americium, curium, berkelium and californium. Understanding how these elements bond with other atoms (known as coordination chemistry), how they behave in water and how they can be separated from one another is crucial for safer nuclear waste management, new reactor technologies and…

LLNL scientist Gianpaolo Carosi (right) discusses the inner workings of the Axion Dark Matter eXperiment. Expertise in this cavity technology (shown here plated in copper) is enhancing current efforts in quantum computing.

Finding resonance: How LLNL expertise is amplifying collaboration in quantum computing

In November, the Department of Energy Office of Science renewed the Superconducting Quantum Materials and Systems Center (SQMS), hosted by Fermi National Accelerator Laboratory, with $125 million over the next five years to accelerate breakthroughs in quantum information science. The investment continues to unite more than 300 experts from 43 partner institutions across…

Cerium, thorium, and zirconium Keggin complexes form parallel arrangements (blue), whereas plutonium complexes organize themselves in a perpendicular fashion (pink)

LLNL researchers discover new way to ‘cage’ plutonium

Plutonium (Pu) exhibits one of the most diverse and complex chemistries of any element in the periodic table. Since its discovery in 1940, scientists have synthesized and studied many different types of plutonium-containing compounds using tools that reveal both their atomic structures and how they interact with light. Not only does plutonium have numerous alloys and…

LLNL scientists Colin Ponce and Carolyn Fisher initiated and led a cross-disciplinary team that developed a machine learning model to distinguish opioids from other chemicals.

Fentanyl or phony? Machine-learning algorithm learns to pick out opioid signatures

New forms of fentanyl are created every day. For law enforcement, that poses a challenge: how do you identify a chemical you’ve never seen before? Researchers at Lawrence Livermore National Laboratory (LLNL) aim to answer that question with a machine-learning model that can distinguish opioids from other chemicals with an accuracy over 95% in a laboratory setting. The…

Dark matter warps space-time, creating distortions in images like the mysterious arcs

What is dark matter? Explore the possibilities in the Big Ideas Lab podcast

Galaxies spin faster than they should. Clusters of those galaxies hold themselves intact against all expectations. By every visible measure, the universe should not look the way it does. Something is holding galaxies, stars and entire clusters together. Something we can’t see. And although it’s invisible to the naked eye, there are clues everywhere that allude to its…

The PROSPECT-I detector studies neutrinos at Oak Ridge National Laboratory’s High Flux Isotope Reactor

Meet the strangest particle in physics in the latest episode of the Big Ideas Lab podcast

There are particles in our universe so unique and so strange that they can shift form mid-flight. They’re as old as time, coming from the beginning of the universe, stars, nuclear reactions and the earth. And they’re everywhere — even passing through you at this very second: neutrinos. Studying these mysterious particles may unlock answers to some of humanity’s most…

NIF target assembly

Measuring nuclear reactions found inside stars

Radiochemistry experts at Lawrence Livermore National Laboratory (LLNL) recently made the first experimental measurements of nuclear reactions in high-energy-density plasma environments, which are similar to conditions found in stars, as well as thermonuclear explosions. According to John Despotopulos, an LLNL radiochemist who leads the research team, the ability to…

James Foot, a 2024 LLNL intern, is pictured with the second-generation Large Area Picosecond Photodetector

Next-generation light sensors for neutrino detection

Detecting neutrinos and other elusive subatomic particles often relies on capturing tiny flashes of light produced when these particles interact with specialized detection media. In water-based scintillators, there is a competition between Cherenkov light (which is faint but directional and prompt) and scintillation light (which is strong but uniformly emitted and delayed)…