Global carbon emissions from inland waters such as lakes, rivers, streams and ponds are being undercounted by about 13% and will likely continue to rise given climate events and land use changes, Oak Ridge National Laboratory scientists found.

A multi-lab research team led by Paul Kent of Oak Ridge National Laboratory is developing a computer application called QMCPACK to enable precise and reliable predictions of the fundamental properties of materials critical in energy research.

The application uses quantum Monte Carlo simulations to compute material properties down at the level of atoms and electrons. Simulation data will complement experimental data in discovering new materials to improve energy technology from batteries to generation methods. 

Oak Ridge National Laboratory researchers demonstrated a process for producing a moisture-stable, lightweight thermal insulation material using hollow silica particles, or HSPs.

Thermal materials insulate refrigerators, building envelopes, energy storage systems, fuel cells, heat exchangers and combined heat and power systems. Commonly made from glass fiber, mineral wool or polystyrene, these materials also require thick layers that take up significant space within building equipment and envelopes, which in turn lowers energy efficiency.

Researchers at Oak Ridge National Laboratory explored radium’s chemistry to advance cancer treatments using ionizing radiation.

Radium-223 is a radioisotope used to treat cancer that has spread to bones. Chemically, radium behaves like calcium inside the body and is readily adsorbed by bones, where it destroys cancer cells and lessens pain for patients. Radium therapy has the potential to treat other forms of cancer, but insights on radium’s chemistry are needed.

The Department of Energy’s Oak Ridge National Laboratory has been selected to lead an Energy Frontier Research Center, or EFRC, focused on polymer electrolytes for next-generation energy storage devices such as fuel cells and solid-state electric vehicle batteries.