Massively parallel holography at high resolutions. (a) A lithographic test sample imaged by scanning electron microscopy (SEM) next to a 30-nm-thick twin-prime 71x73 array with 44-nm square gold scattering elements. The scale bar is 2 mm. (b) The diffraction pattern collected at the ALS (1 x 106 photons in a five second exposure, 200 mm from the sample). (c) The real part of the reconstructed hologram. d) The simulation with 1 x 106 photons. The grey scale represents the real part of the hologram. (e) A simulation with the same number of photons, but a single reference pinhole. (f) Line through the two dots indicated in image (c). (Credit: Image courtesy of DOE/Lawrence Livermore National Laboratory) From Science Daily:
ScienceDaily (Sep. 18, 2008) — It's not easy to see a single molecule inside a living cell. Nevertheless, researchers at Lawrence Livermore National Laboratory are helping to develop a new technique that will enable them to create detailed high-resolution images, giving scientists an unprecedented look at the atomic structure of cellular molecules.
The LLNL team is collaborating with scientists across the country and in Germany and Sweden to utilize high-energy X-ray beams, combined with complex algorithms, to overcome difficulties in current technology.
The work began more than five years ago as a Laboratory Directed Research and Development (LDRD) project, headed by Stefano Marchesini. He has since transferred to Lawrence Berkeley Lab (LBNL), leaving the project in the hands of Stefan Hau-Riege, a materials science physicist at LLNL.
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