Science and Technology Highlights

Elizabeth Grace (LLNL, right) and Filip Grepl (ELI Beamlines, left) assemble the PROBIES diagnostic, one of many instruments that fed data to the machine-learning optimizer algorithm.

May 17, 2024 // S&T Highlights

Machine learning optimizes high-power laser experiments

LLNL international scientists and collaborators collaborate on an experiment to optimize a high-intensity, high-repetition-rate laser using machine learning.

May 14, 2024 // S&T Highlights

Lab study on climate sensitivity earns top notch in list of influential researc…

The American Geophysical Union showcases a paper by LLNL scientists and collaborators on global climate models.

Unveiled at the International Supercomputing Conference in Germany, the June 2024 Top500 lists three systems with identical components — one computing rack each from El Capitan’s “Early Delivery System” (EDS), LLNL’s newest unclassified supercomputer RZAdams and its unclassified “sister” system Tuolumne. All three registered 19.65 petaFLOPs on the High Performance Linpack (HPL) benchmark, ranking them among the world’s 50 fastest.

May 13, 2024 // S&T Highlights

LLNL’s El Capitan debuted on new Top500 list of world’s most powerful supercomp…

Three new systems currently or soon-to-be sited at LLNL debuted on the latest Top500 list of most powerful supercomputers in the world.

Project DarkStar leverages artificial intelligence and machine learning to optimize shaped charges—explosive devices used to manipulate metals.

May 13, 2024 // S&T Highlights

Manufacturing optimized designs for high explosives

LLNL researchers couple computing capabilities and manufacturing methods to rapidly develop and experimentally validate modifications to a shaped charge.

Artwork illustrating a new study combining atomistic simulations, machine learning potential, and data-driven methods to study the chemical speciation of amorphous carbon nitride using X-ray absorption near-edge structure (XANES) spectra.

May 10, 2024 // S&T Highlights

Accelerating material characterization: Machine learning meets X-ray absorption…

LLNL scientists develop a new approach that can rapidly predict the structure and chemical composition of heterogeneous materials.

In a groundbreaking development for addressing future viral pandemics, a multi-institutional team involving Lawrence Livermore National Laboratory researchers has successfully combined an artificial intelligence-backed platform with supercomputing to redesign and restore the effectiveness of antibodies whose ability to fight viruses has been compromised by viral evolution. The work was published in the journal Nature.

May 8, 2024 // S&T Highlights

GUIDE team develops approach to redesign antibodies against viral pandemics

A multi-institutional team involving LLNL researchers successfully combines an artificial intelligence (AI)-backed platform with supercomputing to redesign and restore antibody effectiveness.

A 2D MARBL simulation of the N210808 “Burning Plasma” shot performed at the National Ignition Facility at the onset of ignition. This calculation consists of 19 million high-order quadrature points and ran on rzAdams (on AMD MI300A GPUs).

April 24, 2024 // S&T Highlights

LLNL team accelerates multi-physics simulations with El Capitan predecessor sys…

Researchers at LLNL accelerate and add features to complex multi-physics simulations run on Graphics Processing Units (GPUs), a development that could advance high performance computing and engineering.

Opportunistic pathogenic species, such as Acinetobacter, are prevalent in combat wound infections and commonly found on the gear of U.S. military service members.

April 18, 2024 // S&T Highlights

Mitigating the risk of infection in combat-related injuries

To support the early detection of potentially detrimental microbial factors, LLNL researchers have developed a targeted panel for the capture and sequencing of microbial genomic signatures.