Contributions to LIGO have come from many Stanford teams, including SLAC, Applied Physics, Mechanical Engineering, Aeronautics and Astronautics and the School of Earth, Energy...
A new study with the LCLS X-ray laser could change the way researchers take atomic-level snapshots of important biological machineries, potentially affecting research in...
The 2010 experiment marked a significant step forward in understanding extreme states of matter at the hearts of stars, planets and nuclear fusion reactions.
View photos of upgrades and new equipment at the Stanford Synchrotron Radiation Lightsource (SSRL) that will enable scientists to study photosynthesis, superconductors and other...
A process developed by Stanford and SLAC scientists has potential for scaling up to manufacture clear, flexible electrodes for solar cells, displays and other...
It will provide new insights into the physics of black holes, the formation of chemical elements, stars and galaxies, and the evolution of the universe itself.
Contributions to LIGO have come from many Stanford teams, including SLAC, Applied Physics, Mechanical Engineering, Aeronautics and Astronautics and the School of Earth, Energy and Environmental Sciences.
A new study with the LCLS X-ray laser could change the way researchers take atomic-level snapshots of important biological machineries, potentially affecting research in drug development, clean energy production and many more areas.
For the first time in three years, LCLS has added a new instrument to its set of experimental stations. See photos of the brand new MFX hutch, LCLS’s seventh instrument.
The 2010 experiment marked a significant step forward in understanding extreme states of matter at the hearts of stars, planets and nuclear fusion reactions.
Researchers at SLAC have found a simple new way to study very delicate biological samples – like proteins at work in photosynthesis and components of protein-making machines called ribosomes – at the atomic scale using SLAC's X-ray laser.
View photos of upgrades and new equipment at the Stanford Synchrotron Radiation Lightsource (SSRL) that will enable scientists to study photosynthesis, superconductors and other fields of research.
Scientists working at SLAC have for the first time directly observed a phenomenon that allows magnetic waves to travel a long distance with no resistance.
A team led by SLAC scientists combined powerful magnetic pulses with some of the brightest X-rays on the planet to discover a surprising 3-D effect that appears linked to a mysterious phenomenon known as high-temperature superconductivity.
A process developed by Stanford and SLAC scientists has potential for scaling up to manufacture clear, flexible electrodes for solar cells, displays and other electronics.
