A research team uncovered a surprising, self-improving property in a silicon/gallium nitride photosynthesis device that contributes to the material’s highly efficient and stable performance in converting light and water into carbon-free hydrogen.

Twenty years of Livermore research has revealed the mechanisms behind plutonium’s slow migration through the environment.

Researchers are improving the modeling of drizzle in stratocumulus clouds to enhance the accuracy of climate models.

Using a real-world application for quantum mechanics, Laboratory researchers are finding ways to make hydrogen fuel tanks more efficient.

Livermore researchers are developing a simple, yet powerful, health assessment tool for use on the battlefield, in space, or in other isolated settings.

Livermore’s Inertial Confinement Fusion program brings unparalleled value to the nation.

New research shows that naturally occurring climate variations help to explain a long-standing difference between climate models and satellite observations of global warming.

Livermore scientists have developed a new framework and an accompanying visualization tool that leverages deep reinforcement learning for symbolic regression problems,

Wthin the last 1.1 million years, Greenland had thriving vegetation and ecosystems.

Researchers have shown how applying pressure to a specific thermoelectric material, TiNiSn, increases its efficiency and leads to a structural phase transition.