Science Highlights | U.S. DOE Office of Science (SC)

Water Gunks Up Biofuels Production from Bio-Oils

New findings will help extend the lifetime of catalysts used to process bio-oils in liquid systems.

Heat-Loving Microbe Engineered to Produce Bioalcohols for Fuel

Study reports first significant alcohol production by an archaeon.

Microbial Community Dynamics Dominate Greenhouse Gas Production in Thawing Permafrost

Advances in simulating biogeochemical processes in permafrost will improve predictions of potential impacts on climate.

Work Together or Go It Alone? Microbes Are Split on the Answer

Microbes often evolve and work together to thrive in no oxygen situations, hinting at how carbon and energy flow just below soils and sediments.

New Understanding of One of Nature’s Best Biocatalysts for Biofuels Production

Discovery of a new enzyme system sheds further light on a microbe’s ability to efficiently break down inedible plant matter for conversion to biofuels and biobased chemicals.

Thermal properties of a black phosphorus nanoribbon were a factor of two different along two directions in the crystal structure.

Keeping Cool with a Black Semiconductor

The orientation-dependent thermal properties of black phosphorous could be used to keep microchips cool and improve their efficiency.

Scientists achieved a seamless connection between two disparate materials: a graphene sheet and boron nitride nanotube, as depicted in the bottom overlay by a gray sheet and pink and purple tube.

Working Better Together: Two Materials Defining the Future of High-Speed Electronics

Junctions between conductive graphene and insulating nanotubes could lead to faster electronics and computers.

A snapshot from a large quantum molecular dynamics simulation of the production of hydrogen molecules (green) from an aluminum-lithium alloy nanoparticle containing 16,661 atoms (represented by the silver contour of charge density) and dissolved charged lithium atoms (red).

Towards Eco-friendly Industrial-Scale Hydrogen Production

Atomic-scale simulations predict how to use nanoparticles to increase hydrogen production.

A cage-like protein (gray) called ferritin was engineered to have metal hubs (blue) on its surface.

Modular Construction - on a Molecular Scale

Predictable assembly of protein building blocks result in a new class of porous materials, with potential uses ranging from efficient fuel storage to practical carbon capture and conversion.