This observation paves the way for a deeper understanding of high-temperature superconductivity and future applications for quantum computing.
A simple, robust catalyst is capable of both water oxidation and carbon dioxide splitting, two difficult yet key reactions for solar energy conversion.
Discovering how polymer organization on the molecular level affects electric charge movement in organic solar cells.
Researchers use Oak Ridge Leadership Computing Facility to accelerate drug discovery.
Particle may help explain the origins of mass.
Thomas Jefferson Laboratory lends expertise in cryogenics developments.
Discovery could provide a deeper understanding of the dynamics of the three quarks enslaved inside the nucleon.
Precision analytical techniques developed for fundamental experiments in nuclear physics now enable routine measurements of ultra-low concentrations of Krypton radioisotopes in samples of water, ice, and gas.
Squeezing creates new class of material built from clusters of carbon atoms.
Enzymes originating from marine sponges were intentionally altered to create a new enzyme that can make semiconductors in artificial cells.
House-of-Cards structure leads to improved zeolite catalyst.
Novel, liquid-less design promises to improve long-term stability and durability of dye-sensitized solar cells while hitting high efficiency marks.
