![Simulating Turbulent Bubbly Flows in Nuclear Reactors - two particle chambers and a spectrum on top of a heat like flow with a green background](/-/media/ascr/images/highlights/2018/ASCR-2018-05-a-lrg.jpg?h=618&w=927&la=en&hash=9DDD9D20D6A3A034C33631585E41E4795B7872957211AD0BE81EE3829EC2481D)
Simulating Turbulent Bubbly Flows in Nuclear Reactors
With a better understanding of bubbly flows, researchers can improve the safety and operation of our nuclear reactors.
With a better understanding of bubbly flows, researchers can improve the safety and operation of our nuclear reactors.
Study reveals surprising, bad chemical reactivity in battery components previously considered compatible.
Scientists use ion beams to write high-purity metal structures, enabling nanofabrication opportunities.
Water changes how cobalt-based molecule turns carbon dioxide into chemical feedstock.
Window material repeatedly switches from being see-through to blocking the heat and converting sunlight into electricity.
Scientists used an intense light to unveil hidden rivers that transport electricity with no loss.
Neutron probes and theory reveal how electrons cooperate at lower temperatures.
Scientists are developing better models that describe both neutrino and antineutrino data, which can offer insights into the nature of the universe.
Neutral pion production is a major character in a story of mistaken identity worthy of an Agatha Christie novel.
MicroBooNE neutrino experiment cuts through the noise, clearing the way for signals made by the hard-to-detect particle.
New spectroscopic technique measures heat in itty-bitty volumes that could reveal insights for electronics and energy technology.
Scientists use new X-ray technique to see how water moves at the molecular level.