PNNL's newest solvent captures carbon dioxide from power plants for as little as $47.10 per metric ton, marking a significant milestone in the journey to lower the cost of carbon capture.
On the looming 10th anniversary of the Fukushima disaster at the Daiichi Power Station in Japan, PNNL looks back at the science and solidarity it has shared with Fukushima and its nuclear cleanup effort.
Innovative technology combines continuous, remote, real-time testing and monitoring of byproduct gasses, paving the way for faster advanced reactor development and testing.
As he prepares to enter PNNL's Energy Sciences Center later this year, Vijayakumar 'Vijay' Murugesan is among DOE researchers exploring solutions to design and build transformative materials for batteries of the future.
PNNL streamlines environmental review process for advanced reactors, saving years and millions of dollars toward deployments of new nuclear power projects.
New 140,000-square-foot facility will advance fundamental chemistry and materials science for higher-performing, cost-effective catalysts and batteries, and other energy efficiency technologies.
Understanding the choices and recommendations of artificial intelligence systems is crucial, especially when the stakes are high, as they are with national security issues like nuclear nonproliferation. A PNNL team is using explainable AI to further the effectiveness of AI systems.
PNNL's Jan Strube and colleagues from Germany and Japan outline the future of particle physics research using linear colliders, which could improve our understanding of dark matter and help answer fundamental questions about the universe.
The largest and most detailed molecular analysis yet of an aggressive brain cancer, called glioblastoma, reveals fundamental details that drive its growth. The
Methane emissions from coal mining are likely much higher than previously calculated, according to new research. That’s due mainly to emissions from abandoned mines and higher methane content in deep coal seams.
A recent special issue in The Journal of Chemical Physics highlights PNNL’s contributions to developing two prominent open-source software packages for computational chemistry used by scientists around the world.
The Marine and Coastal Research Laboratory in Sequim, Washington, is the U.S. Department of Energy’s only marine research facility. It has a rich history and expanding research scope.
PNNL researchers are examining the volatile radioisotope iodine as it evolves in the atmosphere and as it lands on a filtering surface. A more detailed understanding of the interactions and chemical evolution of radioiodine could help first responders’ decision-making after the release of volatile iodine into the environment, which happened following nuclear power plant accidents in 1986 at Chernobyl and in 2011 at Fukushima.
Urban landscapes and human-made aerosols have the potential to not only make gusts stronger and hail larger; they can also start storms sooner and even pull them toward cities, according to new research exploring the impact of urban development on hazardous weather, led by PNNL researchers.
California and other areas of the U.S. Southwest may see less future winter precipitation than previously projected by climate models. After probing a persistent error in widely used models, PNNL researchers estimate that California will likely experience drier winters in the future than projected by some climate models, meaning residents may see less spring runoff, higher spring temperatures, and an increased risk of wildfire in coming years.
A multi-institutional effort led to the design of a highly active and more durable catalyst made from cobalt, which sets the foundation for fuel cells to power transportation, stationary and backup power, and more.
A special issue of the Marine Technology Society Journal focuses on research and development efforts among industry, academia, and national laboratories, including PNNL. The issue was guest edited by Alicia Gorton, a project manager and ocean engineer at PNNL.
Scientists have improved a promising battery technology, creating a single-crystal, nickel-rich cathode that is hardier and more efficient than before. Increasing nickel content in the cathode of an electric vehicle’s battery is attractive because of nickel’s relatively low cost, wide availability and low toxicity compared to other materials.
A PNNL-led study is noting a strategic approach is needed for advancing effective large-scale ecosystem restoration outcomes to maximize both ecological and economic benefits.
Using public data from the entire 1,500-square-mile Los Angeles metropolitan area, PNNL researchers reduced the time needed to create a traffic congestion model by an order of magnitude, from hours to minutes.
Two Pacific Northwest National Laboratory researchers, one a world-leading authority on microorganisms and their impact on soil and human health, and the other an expert on coastal ecosystem restoration, have been elected fellows of the American Association for the Advancement of Science.
A recent study found that 2 to 3 gigawatts of electricity from winds off the coast of Oregon could be carried by current transmission lines. That’s enough to power up to 1 million homes—a significant number since there are 1.5 million homes in Oregon. But just as significantly, it also means that delivering that power would not require much additional investment in new transmission infrastructure.
PNNL researchers have shown an improved binarized neural network can deliver a low-cost and low-energy computation to help the performance of smart devices and the power grid.
PNNL’s longstanding grid and buildings capabilities are driving two projects that test transactive energy concepts on a grand scale and lay the groundwork for a more efficient U.S. energy system.
A new report outlines future research paths that are needed for airlines to reduce carbon emissions and notes that the only way to achieve emission reduction goals is with Sustainable Aviation Fuels.
OmniScreen is an end-to-end pipeline for quickly and effectively distinguishing a plethora of pathogenic cells in a microbial community. The system extracts, probes, and screens thousands of cells to pick out pathogens in a matter of days.
PNNL’s new Smart Power Grid Simulator, or Smart-PGsim, combines high-performance computing and artificial intelligence to optimize power grid simulations without sacrificing accuracy.
Scientists have developed a novel catalyst that converts pure ethanol into a highly valued class of alcohols that can serve as building blocks for everything from solvents to jet fuel.
Micro- and nanoplastics were not absorbed by plant cells but did attach to the root cap. This could bode well for future cleanup of contaminated environments, but not well for root crops, like carrots.
PNNL scientists are working with local doctors to collect and analyze air samples from patients’ lungs, looking for protein patterns unique to patients with COVID-19.
PNNL researchers are contributing expertise and hydrothermal liquefaction technology to a project that intercepts toxic algae blooms from water, treats the water, and concentrates algae for transformation to biocrude.
PNNL is taking new approaches to solve cybersecurity vulnerabilities for utilities and other industries that use process control technologies. Working with utility advisors and companies that specialize in identifying vulnerabilities, PNNL researchers have developed two web-based tools to assess and mitigate threats.
An international research team led by PNNL has published a vision for electron microscopy infused with the latest advances in data science and artificial intelligence. Writing a commentary in Nature Materials, the team proposes a highly integrated, autonomous, and data-driven microscopy architecture to address challenges in energy storage, quantum information science, and materials design.
PNNL researchers established an Internet of Things Common Operating Environment (IoTCOE) laboratory to explore the risks associated with IoT connectivity to the internet, the energy grid and other critical infrastructures.
For the past year, three small-scale x-ray spectroscopy devices tucked away at Pacific Northwest National Laboratory (PNNL) have begun to dramatically speed up the testing and analysis of candidate novel materials used in energy storage research and environmental remediation. They are also expected to reduce the number of expensive off-site research trips.