Your search keyword '"Siljeström, S."' showing total 3 results

1. Intricate tunnels in garnets from soils and river sediments in Thailand - Possible endolithic microborings.

Author

Ivarsson M, Skogby H, Phichaikamjornwut B, Bengtson S, Siljeström S, Ounchanum P, Boonsoong A, Kruachanta M, Marone F, Belivanova V, and Holmström S

Subjects

Ferrous Compounds chemistry, Fossils, Geologic Sediments microbiology, Microscopy, Electron, Scanning, Spectrometry, X-Ray Emission, Thailand, Geologic Sediments chemistry, Minerals chemistry, Rivers chemistry, Silicates chemistry, Soil chemistry

Abstract

Garnets from disparate geographical environments and origins such as oxidized soils and river sediments in Thailand host intricate systems of microsized tunnels that significantly decrease the quality and value of the garnets as gems. The origin of such tunneling has previously been attributed to abiotic processes. Here we present physical and chemical remains of endolithic microorganisms within the tunnels and discuss a probable biological origin of the tunnels. Extensive investigations with synchrotron-radiation X-ray tomographic microscopy (SRXTM) reveal morphological indications of biogenicity that further support a euendolithic interpretation. We suggest that the production of the tunnels was initiated by a combination of abiotic and biological processes, and that at later stages biological processes came to dominate. In environments such as river sediments and oxidized soils garnets are among the few remaining sources of bio-available Fe2+, thus it is likely that microbially mediated boring of the garnets has trophic reasons. Whatever the reason for garnet boring, the tunnel system represents a new endolithic habitat in a hard silicate mineral otherwise known to be resistant to abrasion and chemical attack., Competing Interests: The authors have declared that no competing interests exist.

Published

2018

2. Structural effects of C60 + bombardment on various natural mineral samples—Application to analysis of organic phases in geological samples

Author

Siljeström, S., Lausmaa, J., Hode, T., Sundin, M., and Sjövall, P.

Subjects

*ION bombardment, *MINERALS, *SPACE biology, *GEOCHEMISTRY, *CARBON compounds, *GEOBIOLOGY, *FOSSILS, *FLUID inclusions

Abstract

Abstract: Organic phases trapped inside natural mineral samples are of considerable interest in astrobiology, geochemistry and geobiology. Examples of such organic phases are microfossils, kerogen and oil. Information about these phases is usually retrieved through bulk crushing of the rock which means both a risk of contamination and that the composition and spatial distribution of the organics to its host mineral is lost. An attractive of way to retrieve information about the organics in the rock is depth profiling using a focused ion beam. Recently, it was shown that it is possible to obtain detailed mass spectrometric information from oil-bearing fluid inclusions, i.e. small amounts of oil trapped inside a mineral matrix, using ToF-SIMS. Using a 10keV C60 + sputter beam and a 25keV Bi3 + analysis beam, oil-bearing inclusions in different minerals were opened and analysed individually. However, sputtering with a C60 + beam also induced other changes to the mineral surface, such as formation of topographic features and carbon deposition. In this paper, the cause of these changes is explored and the consequences of the sputter-induced features on the analysis of organic phases in natural mineral samples (quartz, calcite and fluorite) in general and fluid inclusions in particular are discussed. The dominating topographical features that were observed when a several micrometers deep crater is sputtered with 10keV C60 + ions on a natural mineral surface are conical-shaped and ridge-like structures that may rise several micrometers, pointing in the direction of the incident C60 + ion beam, on an otherwise flat crater bottom. The sputter-induced structures were found to appear at places with different chemistry than the host mineral, including other minerals phases and fluid inclusions, while structural defects in the host material, such as polishing marks or scratches, did not necessarily result in sputter-induced structures. The ridge-like structures were often covered by a thick layer of deposited carbon. Despite the appearance of the sputter-induced structures and carbon deposition, most oil-bearing inclusions could successfully be opened and analysed. However, smaller inclusion (<15μm) could potentially become entirely covered by sputter-resistant structures and therefore difficult to open. Therefore, it might become necessary, to for example increase the ion energy and rotate the stage to successfully open smaller inclusions for analysis. SIMS, C60, carbon deposition, topography, mineral, fluid inclusions, geological samples, depth profiling. [Copyright &y& Elsevier]

Published

2011

3. CHARACTERIZATION OF MINERALS BY LASER DESORPTION/ABLATION AND IONIZATION IN PREPARATION OF THE MOMA INVESTIGATION ONBOARD THE EXOMARS ROVER.

Author

Goetz, W., Arevalo, Jr, R. D., Oehlke, M., Danell, R., Siljeström, S., Kronz, A., John, H., Pinnick, V., Brinckerhoff, W. B., Steininger, H., Goesmann, F., and Raulin, F.

Subjects

MINERALS, DESORPTION

Published

2017