Cars and trucks might one day run on biofuel made from seaweed with the help of two technologies being developed at the Department of Energy's Pacific Northwest National Laboratory.

Professor Tsumoru Shintake at the Okinawa Institute of Science and Technology Graduate University (OIST) yearns for a clean future, one that is affordable and powered by sustainable energy. Originally from the high-energy accelerator field, in 2012 he decided to seek new energy resources—wind and solar were being explored in depth, but he moved toward the sea instead.

Technologies that allow the preservation of scarce fossil resources will pave the way towards resource security. The two main factors that contribute to a sustainable future industry are the source of electric energy and the carbon feedstock. First, the electrical power production based on renewable resources, such as wind and solar energy, is promoted. Second, renewable feedstocks and waste streams are considered as valuable precursors for the production of commodities and fuels. Building a bridge between both factors means linking the conversion of electric energy - especially from local peak productions - to chemical energy carriers and commodities. Researchers in a consortium led by Dr. Falk Harnisch from the UFZ show that this bridge can be build.

Many of the cities in northern Japan damaged by the 2011 earthquake and tsunami are building back their electric grids with renewable energy and micro-grids — bucking the nation’s old, centralized utility system by making communities in the region self-sufficient in generating electricity, Reuters reported.

The Scottish and UK oil industries are entering their final decade of production, research suggests.

A study of output from offshore fields estimates that close to 10 per cent of the UK’s original recoverable oil and gas remains – about 11 per cent of oil and nine per cent of gas resources.

The analysis also finds that fracking will be barely economically feasible in the UK, especially in Scotland, because of a lack of sites with suitable geology.

Without setting foot from her office, Heather Kulik, the Joseph R. Mares '24 Career Development Assistant Professor of Chemical Engineering, is charting unknown worlds. Her discoveries plumb “vast regions of chemical space,” she says, a domain comprised of combinations of chemical elements that do not yet exist. “Best estimates indicate that we have likely made or studied only about 1 part in 10 to the 50th of that chemical space,” she says.

Scientists at the National Institute of Standards and Technology (NIST) have developed a laboratory instrument that can measure how much of the carbon in many carbon-containing materials was derived from fossil fuels. This will open the way for new methods in the biofuels and bioplastics industries, in scientific research, and environmental monitoring. Among other things, it will allow scientists to measure how much of the carbon dioxide (CO2) in the atmosphere came from burning fossil fuels, and to estimate fossil fuel emissions in an area as small as a city or as large as a continent.

As patients at Lucile Packard Children’s Hospital Stanford undergo routine medical procedures, they are being whisked away to swim under the sea, zap flying cheeseburgers in outer space, catch basketballs using their heads and fly on paper airplanes through the sky, thanks to virtual-reality technology, which is being implemented throughout the hospital to help ease patients’ feelings of pain and anxiety.

Packard Children’s is one of the first hospitals in the country to begin implementing distraction-based VR therapy within every patient unit.

A discovery by Indiana University researchers could advance the long-term storage of nuclear waste, an increasingly burdensome and costly task for the public and private agencies that protect people from these harmful chemicals.

A new study evaluating models of future climate scenarios has led to the creation of the new risk categories “catastrophic” and “unknown” to characterize the range of threats posed by rapid global warming. Researchers propose that unknown risks imply existential threats to the survival of humanity.

These categories describe two low-probability but statistically significant scenarios that could play out by century’s end, in a new study by Veerabhadran Ramanathan, a distinguished professor of climate and atmospheric sciences at Scripps Institution of Oceanography at the University of California San Diego, and his former Scripps graduate student Yangyang Xu, now an assistant professor at Texas A&M University.