See content related to X-ray scattering and X-ray diffraction here below.
Three dimensional visualization of diffraction intensities determined by combining over 15,000 individual single-shot diffraction patterns from the photosystem I protein complex, acquired using LCLS.
(Thomas White/CFEL)
Using SLAC’s X-ray synchrotron SSRL, Wang improves fundamental knowledge about how cells communicate, which could enable the development of more effective drugs.
Experiments at SLAC’s X-ray laser reveal in atomic detail how two distinct liquid phases in these materials enable fast switching between glassy and crystalline...
Scientists precisely control where single-atom catalysts sit on their support structures, and show how changing their position affects their reactivity.
A new method could be used to look at chemical reactions that other techniques can’t catch, for instance in catalysis, photovoltaics, peptide and combustion...
Using SLAC’s X-ray synchrotron SSRL, Wang improves fundamental knowledge about how cells communicate, which could enable the development of more effective drugs.
Experiments at SLAC’s X-ray laser reveal in atomic detail how two distinct liquid phases in these materials enable fast switching between glassy and crystalline states that represent 0s and 1s in memory devices.
Scientists precisely control where single-atom catalysts sit on their support structures, and show how changing their position affects their reactivity.
A new method could be used to look at chemical reactions that other techniques can’t catch, for instance in catalysis, photovoltaics, peptide and combustion research.