Laboratory X-ray microscopy for high-resolution imaging of environmental colloid structure

Transmission X-ray microscopy is a uniquely suited technique for studies of environmental colloids since it allows imaging in aqueous media with high spatial resolution, presently down to the 20nm range. Such nano-scale morphological description of these high-specific-surface-area compounds show pro...

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Bibliographic Details
Published in:Chemical geology 2012-11, Vol.329 (SI), p.26-31
Main Authors: Hertz, H.M., Bertilson, M., v. Hofsten, O., Gleber, S.-C., Sedlmair, J., Thieme, J.
Format: Article
Language:English
Subjects:
Diffractive optics
Environmental colloids
Laboratory scale
Laser plasma
Soils
X-ray microscopy
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Summary:Transmission X-ray microscopy is a uniquely suited technique for studies of environmental colloids since it allows imaging in aqueous media with high spatial resolution, presently down to the 20nm range. Such nano-scale morphological description of these high-specific-surface-area compounds show promise for improved understanding of soils, sediments or groundwater aquifers. However, present high-quality X-ray microscopes are located at synchrotron radiation facilities resulting in limited applicability and accessibility for colloid scientists. Here we investigate the applicability of a laboratory-scale transmission X-ray microscope for studies of colloids of the environment. The microscope is based on a laser-plasma source in combination with multilayer and zone plate optics. Samples are held at atmospheric pressure in their natural wet state. We show images revealing the nano-scale morphology of the clay nontronite, soils such as chernozem and luvisol, and the mineral hematite, an iron oxide. Comparative studies of dried substances clearly show the need for imaging in the wet state. The image quality approaches that of synchrotron-based microscopes, albeit at longer exposure times. Stereo imaging is investigated as a means for giving 3D information with shorter exposure times than tomography requires. Finally the future development of the laboratory X-ray microscope is discussed, especially with regard to the reduction of exposure times. ► High-resolution laboratory X-ray microscopy. ► Nano-scale imaging in wet state. ► Laboratory X-ray nano-imaging of soils.
ISSN:0009-2541
1872-6836
1872-6836
DOI:10.1016/j.chemgeo.2011.07.012