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Showing 1–4 of 4 results
Advanced filters: Author: Guillaume Potdevin Clear advanced filters

  • Researchers create high ionization states, up to Xe36+, using 1.5 keV free-electron laser pulses. The higher than expected ionization may be due to transient resonance-enhanced absorption and the effect may play an important role in interactions of intense X-rays with high-Z elements and radiation damage.

    • Benedikt Rudek
    • Sang-Kil Son
    • Daniel Rolles
    Research
    Nature Photonics
    Volume: 6, P: 858-865

  • The start-up of the new femtosecond hard X-ray laser facility in Stanford, the Linac Coherent Light Source, has brought high expectations for a new era for biological imaging. The intense, ultrashort X-ray pulses allow diffraction imaging of small structures before radiation damage occurs. This new capability is tested for the problem of structure determination from nanocrystals of macromolecules that cannot be grown in large crystals. Over three million diffraction patterns were collected from a stream of nanocrystals of the membrane protein complex photosystem I, which allowed the assembly of a three-dimensional data set for this protein, and proves the concept of this imaging technique.

    • Henry N. Chapman
    • Petra Fromme
    • John C. H. Spence
    Research
    Nature
    Volume: 470, P: 73-77

  • The start-up of the new femtosecond hard X-ray laser facility in Stanford, the Linac Coherent Light Source, has brought high expectations for a new era for biological imaging. The intense, ultrashort X-ray pulses allow diffraction imaging of small structures before radiation damage occurs. This new capability is tested for the problem of imaging a non-crystalline biological sample. Images of mimivirus are obtained, the largest known virus with a total diameter of about 0.75 micrometres, by injecting a beam of cooled mimivirus particles into the X-ray beam. The measurements indicate no damage during imaging and prove the concept of this imaging technique.

    • M. Marvin Seibert
    • Tomas Ekeberg
    • Janos Hajdu
    Research
    Nature
    Volume: 470, P: 78-81