Atmospheric,
Earth, & Energy Science

Group leader: Ted Ognibene

Our scientists support the Center for Accelerator Mass Spectrometry (CAMS) at LLNL. With our support, CAMS activities have broad-ranging scientific impacts while also contributing to LLNL mission needs. Scientists working at CAMS have:

• Used diverse analytical techniques and state-of-the-art instrumentation to develop and apply unique, ultra-sensitive isotope ratio measurement and ion-beam analytical techniques to address a broad spectrum of scientific needs for the Laboratory and the nation.
• Provided unique, cross-cutting, program support.
• Delivered high-impact science, publications, and pipelines:
• Our work has been featured on 16 journal covers.
• We host ~60 researchers and students each year.
• Over 30 students and postdocs at CAMS have become LLNL employees.
• Invented BioAMS, which has served as a National Institute of Health-funded research resource for two decades.
• Developed use of cosmogenic isotopes for studying Earth system processes.
• Trained most of the scientists who are now working at AMS labs across the world, with many in leadership roles.

Group leader: Philip Cameron-Smith

Our group brings together expertise in climate model development with systems and data analysis. Our scientists support:

• Intercomparison, evaluation, and analysis of the world’s climate models
• Detection and attribution of human impacts on Earth’s climate
• High-resolution global Earth system model development
• Delivery of high-quality science and scientific leadership, which includes:
• Providing scientific testimony to Congress
• Serving on international and national scientific committees
• Serving as lead chapter-authors for every Intergovernmental Panel on Climate Change (IPCC) climate report and contributing to the 2007 Nobel Prize awarded to IPCC.
• Publishing our research in Science, Nature, and other high-impact journals.

We provide scientific expertise to the Program for Climate Model Diagnosis and Intercomparison (PCDMI), which leads international modeling activities that provide a multi-model perspective of the climate system.

To learn about general climate research at LLNL, visit the Climate Program website.

Group leader: Shaocheng Xie

Our group is a recognized leader in basic research into cloud processes, their diagnosis with observations, their parameterization and evaluation in climate models, and their response to climate change. Researchers in our group support major activities, including:

• Improving the understanding of climate change through the development of novel techniques for model evaluation and observational data analysis as well as next-generation, high-resolution Earth system models.
• Serving as the lead institution involved in developing the Department of Energy’s high-resolution Energy, Exascale, and Earth System Model (E3SM).
• Developing objective analysis methods and diagnostic techniques used worldwide to assess model simulations of clouds and their response to environmental change.
• Creating one of the world’s largest and most respected cloud-feedback research groups.
• Serving in leadership roles for national and international professional societies.
• Working closely with the Program for Climate Model Diagnosis and Intercomparison, a world leader in the diagnosis of climate models, and the Atmospheric Radiation Measurement (ARM), a program that provides novel ground-based observations of clouds and related processes.
• Publishing articles in Science, Nature, and other high-impact journals.

Group leader: Joe Morris

Our group develops and employs cutting-edge software to tackle challenging problems that require understanding and exploiting subsurface processes. A common theme in our work is the employment of novel algorithms on the world’s fastest supercomputers in order to deliver high-fidelity three-dimensional predictions that include a wide range of coupled physical effects. Our projects support a wide range of applications from energy to defense with national and worldwide significance. Our recent projects include:

• Validating enhanced geothermal concepts deep in a retired gold mine
• Improving our ability to monitor and detect underground detonations
• Performing high-fidelity modeling and experiments investigating shock-loading of granular materials

Group leader: A.J. Simon

Our group focuses on energy systems research, including efforts in wind energy, the energy–water nexus, and nuclear risk analysis. Our group consists of atmospheric and land surface modelers, nuclear engineers, and experimentalists who tackle a diverse portfolio of energy projects, including wind power forecasting, carbon capture and sequestration, geothermal reservoir management, advanced nuclear fuel cycle analysis, and resource utilization analyses. Our recent projects include efforts to:

• Measure, model, and analyze the connections between energy systems and the planet’s subsurface, surface, and atmosphere, including:
• Deploying field instruments and interpreting their data to better understand atmospheric flow and land–surface exchange.
• Developing and running models that simulate the interactions between the atmosphere and the built environment.
• Diagnosing and predicting the behavior of complex energy and environmental systems with statistical and machine-learning techniques.
• Performing analysis of material and energy flows through natural and engineered systems.
• Support uniquely interdisciplinary research and operational capabilities:
• The Atmosphere to Electrons (A2e) initiative leverages multiscale atmospheric science coupled to multiphysics turbine engineering models.
• The National Atmospheric Release Advisory Center (NARAC) predicts the fate and transport of nuclear material at the interface between the atmosphere and land surface.
• Research on the energy–water nexus informs sustainable resource management policy.

Our work leads to collaborations with the following programs:

• The Department of Energy’s Preventative Nuclear Detection Program
• The Office of Nuclear Energy
• The Office of Energy Policy and Systems Analysis
• The Wind and Water Power Technologies Program
• The Critical Materials Institute
• The California Energy Commission

We also support LLNL’s nuclear forensics program, NARAC, and LLNL’s Global Security division’s energy and nuclear programs.

To learn about general water research at LLNL, visit the Water Research at LLNL website.

Group leader: Michael Pasyanos

Our group is comprised of over a dozen geophysicists who have expertise in source physics, Earth models, seismic tomography, earthquake location, and microseismicity. Our group’s state-of-the-art research takes advantage of the Lab’s world-class resources, including expertise in managing seismic databases, complex data analysis, and high-performance computing.

In supporting LLNL’s non-proliferation, national security, and energy missions, our researchers have:

• Developed key methods, models, and software for explosion monitoring and forensics.
• Created a high-resolution global 3D Earth model for accurate seismic event locations and tectonic interpretation.
• Provided unique expertise to US policy makers, including support for the Comprehensive Test Ban Treaty Organization, participation in expert panels, capacity building, and contributing authorship for National Academy and National Nuclear Security Administration reports on seismic monitoring.
• Won numerous prestigious awards, including the Fulbright Scholarship and the E.O. Lawrence Award for Non-Proliferation.

Group leader: Joshua White

Our group has a broad range of experimental, computational, and fieldwork expertise related to fluid flow and reactive mass transport phenomena in subsurface and terrestrial environmental systems. We address coupled hydro-chemical-thermal-mechanical phenomena across multiple scales–from the laboratory scale to the field scale–relevant to both natural and engineered applications. We tackle challenges in this field using experimental methods, numerical modeling, and geophysical monitoring techniques. A few of our focus areas include:

• Fate of gases and contaminants from underground nuclear tests
• Design and safety of carbon storage reservoirs
• Degradation of cements and polymers in challenging environments
• Next-generation subsurface simulation software

In these efforts, we routinely interface with other discipline organizations from across the laboratory and from outside institutions in collaborative research, ultimately supporting multiple energy, environmental, and national security missions at LLNL.