Materials Science

Accelerator Complex

Contact: Scott Anderson

LLNL’s accelerator complex houses sophisticated tools to accelerate charged particles to incredibly high speeds. Located three stories underground, these instruments allow our nuclear physicists to detect isotopes, create fast neutrons, peer inside heavily shielded objects, and characterize unknown material.

Additional information is available on the Accelerator Complex webpage.

Actinide Materials

Contact: Scott McCall

We support global and national security missions by maintaining capabilities to synthesize, characterize, and test materials containing actinides.

Animal Care Facility (ACF)

Contact: acf [at] lists.llnl.gov (ACF support)

The Association for Assessment and Accreditation of Laboratory Animals, International (AAALAC)-accredited and Public Health Service (PHS) Assured animal facility houses several thousand small animals, which are cared for by full-time Laboratory animal technologists. Animal models are used in comparative genomics studies that focus on understanding gene regulation and for vaccine and countermeasure development.

Autoradiography Imaging

Contact: Kim Knight

Sub-millimeter resolution alpha and beta radioactivity imaging

Center for Accelerator Mass Spectrometry (CAMS)

Contact: Nanette Sorensen or Scott Tumey

Researchers at CAMS use diverse analytical techniques and state-of-the-art instrumentation to develop and apply unique, ultra-sensitive isotope ratio measurement and ion beam analytical techniques.

Additional information is available on the CAMS website.

Center for Micro- and Nanotechnology (CMNT)

Contact: Engineering Directorate

Researchers at the CMNT invent, develop, and apply microscale and nanoscale technologies to support LLNL missions. The research and capabilities of the Center cover materials, devices, instruments, and systems that require microfabricated components, including microelectromechanical systems (MEMS), electronics, photonics, micro- and nanostructures, and micro- and nanoactuators.

Additional information is available on the Engineering website.

Center for National Security Applications of Nuclear Magnetic Resonance (NMR)

Contact: TBD

The NMR facility provides advanced characterization of chemical processes and materials using magnetically passed spectroscopic capabilities. The center houses multiple spectrometers used to analyze solids, liquids, and gases, including explosives, highly toxic industrial chemicals, and chemical and biological threat agents.

Computational Nuclear Physics

Contact: Bret Beck

We measure, collect, and evaluate nuclear data and incorporate these data into libraries to be used in simulations. We provide nuclear data, physics simulation, and data processing tools for experimental and theoretical nuclear data.

Additional information is available on the Computational Nuclear Physics website.

Cooperative Research Center for NanoScaffold-based Chlamydia trachomatis Vaccines

Contact: Matthew Coleman

Leading experts in immunology and nanotechnology are developing and testing a new type of vaccine to prevent sexually transmitted infections caused by the Chlamydia trachomatis (Ct) pathogen.

Additional information is available on the Cooperative Research Center for NanoScaffold-based Chlamydia trachomatis Vaccines webpage.

Diamond Anvil Cell (DAC) and Ultrafast Science

Contact: Geoffrey Campbell

Our diamond anvil-based laboratories can measure materials properties at static pressures above 1 Mbar, providing essential equation-of-state information for weapons, experiment design, and further study of the chemistries that control unique material formation. Additional experiments to study shock compression with 10 picosecond time resolution are pushing the limits of current theories of the metal strength, phase transitions, and chemical kinetics.

Dynamic Transmission Electron Microscope (DTEM)

Contact: Geoffrey Campbell

The LLNL-developed DTEM enables direct observation of unique mechanical properties controlled by features at the nanoscale.

Additional information is available on the DTEM webpage.

Electron Beam Ion Trap (EBIT)

Contact: Greg Brown

An EBIT makes and traps very highly charged ions by means of a high-current density electron beam. The ions can be observed in the trap itself or extracted from the trap for external experiments. Our EBIT is the only ion source in the world that can create highly charged ions that are practically at rest, allowing us to study an otherwise inaccessible domain.

Additional information is available on the EBIT website.

Electron Microscopy

Contact: Kerri Blobaum

LLNL maintains state-of-the-art capabilities in scanning electron microscopy (SEM) and transmission electron microscopy (TEM) to characterize materials.

Energetic Materials Center (EMC)

Contact: Lara Leininger

The EMC supports research and development for advanced conventional weapons, rocket and gun propellants, homeland security, demilitarization, and industrial applications of energetic materials. Our researchers, as part of the EMC, specialize in the modeling and experimentation surrounding the development, characterization, and effectiveness of high explosives.

Additional information is available on the EMC website.

Feedstocks for Additive Manufacturing

Contact: Yong Han

Our scientists and engineers optimize additive manufacturing (3D printing) techniques, such as direct-ink writing, through focused investments in feedstock development. Using computer programs to simulate particle size and scale, we develop new feedstock materials from combinations of polymers, composites, and ceramics, with applications ranging from weapon components to energy innovations.

Forensic Science Center (FSC)

Contact: Audrey Williams

FSC researchers analyze interdicted samples, provide radiological assistance 24/7, and engage in the critical research and development needs of the intelligence community. FSC expertise includes analytical chemistry, organic chemistry, inorganic chemistry, nuclear chemistry, and forensic instrument design and fabrication.

Additional information is available in the FSC Fact Sheet and on the FSC website.

Glenn T. Seaborg Institute

Contact: Mavrik Zavarin

The LLNL branch of the Glenn T. Seaborg Institute conducts collaborative research between LLNL and the academic community in radiochemistry and nuclear forensics, contributing to the education and training of undergraduate and graduate students, postdocs, and faculty in transactinium science.

Additional information is available on the Seaborg Institute website.

High Energy Density Science (HEDS) Center

Contact: Frank Graziani

The HEDS Center fosters collaborations with university faculty and students that have the potential to enhance high-energy-density science research. The HEDS Center facilitates access to LLNL’s HEDS experimental facilities and high-performance computing resources in order to support research important to the Department of Energy.

Additional information is available on the HEDS Center website.

High Explosives Applications Facility (HEAF)

Contact: Lara Leininger

HEAF houses unique facilities for the synthesis, characterization, and testing of high explosives and other energetic materials. HEAF is also equipped with extensive, high-fidelity, high-speed diagnostic capabilities, including x-ray radiography, high-speed photography, laser velocimetry, and embedded particle velocity/pressure measurements.

Additional information is available on the HEAF webpage.

High-Performance Computing

Contact: lc-support [at] llnl.gov (LC support)

LLNL is home to a first-class computational infrastructure that supports the high-performance computing requirements of the Laboratory’s mission and research scientists. Livermore Computing provides the systems, tools, and expertise needed to enable discovery and innovation through simulations.

Additional information is available on the Livermore Computing Center website.

High-Performance Computing (HPC) Innovation Center

Contact: HPC Innovation Center

LLNL’s HPC Innovation Center connects companies with computational science and computer science experts, on demand, to help them solve their toughest challenges. It also provides cost-effective access to some of the world’s largest HPC systems and rapidly assembles expert teams to develop, prove, and deploy high-impact solutions across a broad range of industries and applications.

Additional information is available on the HPC Innovation Center website.

Joint Genome Institute (JGI)

Contact: Crystal Jaing

The JGI is a high-throughput genome sequencing and analysis facility dedicated to the genomics of nonmedical microbes, microbial communities, plants, fungi, and other targets relevant to DOE mission areas in clean energy generation, climate change, and environmental sciences. Scientists from the Genomics group support key missions of JGI by performing DNA sequencing experiments and sequencing data analysis utilizing unique molecular biology skills and state-of-the-art instrumentation.

Additional information is available on the JGI website.

Jupiter Laser Facility (JLF)

Contact: Elaine Johnson

JLF is a unique laser user facility for research in high-energy-density science. Its diverse laser platforms offer researchers a wide range of capabilities to produce and explore states of matter under extreme conditions of high density, pressure, and temperature.

Additional information is available on the JLF website.

Laboratory for Energy Applications for the Future (LEAF)

Contact: Brandon Wood

LEAF is a multidisciplinary center that develops disruptive technologies for the grid, transportation, and the environment from inception to demonstration.

Additional information is available on the LEAF website.

Mass Spectrometry

Contact: Rachel Lindvall

LLNL’s mass spectrometry instruments offer experimental and diagnostic techniques that make it possible to count atoms, study lunar rocks, isolate isotopes, and characterize unknown material. These sophisticated tools enable our nuclear chemists, cosmochemists, and radiochemists to tackle complex science challenges.

Additional information is available on the Mass Spectrometry webpage.

Nanoscale Synthesis and Characterization Laboratory (NSCL)

Contact: Alex Hamza

NSCL is making advances in science at the intersection of physics, materials science, engineering, and chemistry. We are pursuing research in nanoporous materials, advanced nano crystalline materials, novel 3D nanofabrication technologies, and nondestructive characterization at the mesoscale.

Additional information is available on the NSCL webpage.

National Atmospheric Release Advisory Center (NARAC)

Contact: Lee Glascoe

NARAC is a national support and resource center for planning, real-time assessment, emergency response, and detailed studies of atmospheric releases of nuclear, radiological, chemical, biological, and natural materials. NARAC provides timely and accurate atmospheric plume predictions to aid emergency preparedness and response efforts in protecting the public and the environment.

Additional information is available on the NARAC website.

National Ignition Facility (NIF)

Contact: Patricia Koning

NIF houses the world’s largest and highest-energy laser. NIF’s laser beams routinely create temperatures and pressures similar to those that exist only in the cores of stars and giant planets and inside nuclear weapons. The facilities are a key element of maintaining the reliability and safety of the U.S. nuclear deterrent without full-scale testing.

Additional information is available on the NIF website.

National User Resource for Biological Accelerator Mass Spectrometry (BioAMS)

Contact: Graham Bench

BioAMS makes accelerator mass spectrometry (AMS) available to biomedical researchers who need to accurately measure very low levels of radioisotopes. BioAMS is working to enhance AMS for analysis of radioisotopes in biomedical tracer studies through development of new methods and instrumentation.

Additional information is available on the BioAMS website.

Nuclear Counting Facility (NCF)

Contact: Keenan Thomas

Located two floors below ground, with a layer of shielding materials between floors to minimize background radiation, LLNL’s Nuclear Counting Facility provides high-sensitivity radiation measurements. Its assets include gamma spectrometers, solid-state detectors, alpha and beta counting systems employing ionization gas chambers, and liquid scintillation techniques.

The facility supports research in stockpile stewardship, nonproliferation, and counterterrorism, including:

• Analyzing samples and surrogate materials in support of nuclear forensics efforts.
• Studying samples collected during underground nuclear tests, which ended in 1992.
• Determining the number of radioactive atoms produced during experiments at LLNL’s National Ignition Facility.

Optical Sciences

Contact: Alex Pertica

Our experts develop x-ray adaptive optics systems and optical payloads for nano-satellites. We have explored the use of survey telescopes for dark matter research, developed algorithms and software tools for simulation of orbital space events, and implemented sensor calibration and exploitation strategies for hyperspectral airborne sensors.

Polymer Science

Contact: James Lewicki

We maintain capabilities to synthesize, characterize, and model a broad range of polymeric materials and architectures.