Recent experiments at SLAC's SSRL reveal that an organic semiconductor transports electrical charge more efficiently when combined with the wonder material graphene.
They used synthetic diamond crystals as mirrors to make X-ray pulses run laps inside a vacuum chamber, demonstrating a key process needed for future generations of performance-enhanced X-ray lasers.
Batteries come in many shapes and sizes, but their materials can be hard to source. SLAC researchers are trying to build them with more abundant and ethical elements.
Chemical reactions often involve intermediate steps that are too fast and complex for us to see – even using our most advanced scientific instruments. Combining two X-ray spectroscopy techniques has now been shown to change that.
The SLAC and Stanford professor and SUNCAT director is being honored for groundbreaking work in catalysis, which promotes chemical reactions in thousands of industrial processes.
These stripes of electron spin and charge are exciting because of their possible link to a phenomenon that could transform society by making electrical transmission nearly 100 percent efficient.
SLAC study shows the so-called ‘pseudogap’ hoards electrons that otherwise might pair up to carry current through a material with 100 percent efficiency.