Your search keyword '"Soete, J"' showing total 3 results

1. Elemental geochemistry to complement stable isotope data of fossil travertine: Importance of digestion method and statistics

Author

Claes, H., Huysmans, M., Soete, J., Dirix, K., Vassilieva, E., Marques Erthal, M., Vandewijngaerde, W., Hamaekers, H., Aratman, C., Özkul, M., and Swennen, R.

Subjects

Travertines, Turkey, Multivariant analysis, Subsurface reservoir, sediment chemistry, Elemental concentrations, deposition, Multivariate analyses, Geochemical variables, Isotopes, source rock, travertine, stable isotope, Analytical geochemistry, Stable isotopes, Trace elements, Elemental geochemistry, fossil, Statistics, Major and trace elements, Data acquisition, trace element, degassing, Limestone, Multi variate analysis, Geochemistry, multivariate analysis, diagenesis

Abstract

Elemental data from travertines are a treasure of depositional and diagenetic information. However, correct interpretation requires proper data acquisition and treatment. This study shows how results from elemental analyses complement sedimentological and other geochemical, i.e. isotopic, data and thereby contribute to our understanding of fossil travertines. Multivariate statistical element analyses, after multiple travertine digestion methods, demonstrate the link between elements, their mineralogical phases, and ultimately their origin. This study reveals that carbonate-phase related elements in travertines (Sr, S, Ba, Mg and Na) originate dominantly from the fluid source rocks. In combination with the δ18O and δ13C signatures, they are thus key geochemical variables for comparison of different travertine geobodies. Geochemical data analysis (elemental concentrations and isotope signatures), as illustrated here for the Turkish Ballık travertines, supports interpretation with regard to fluid source rock, distance from the vent and relative intensity of processes like evaporation and degassing. For fossil travertines, geochemical data can thus provide crucial insights for understanding the hydrologic system. In particular when information is restricted to borehole data, like in subsurface reservoirs, their application could be decisive. © 2019 Elsevier B.V.

Published

2019

2. spring carbonate facies: Case study from the Cakmak quarry (Denizli

Author

De Boever, E, Foubert, A, Oligschlaeger, D, Claes, S, Soete, J, Bertier, P, Ozkul, M, Virgone, A, and Swennen, R

Subjects

Travertine Facies, Microporosity, NMR, mu-CT, pore network, Turkey

Abstract

Carbonate spring deposits gained renewed interest as potential contributors to subsurface reservoirs and as continental archives of environmental changes. In contrast to their fabrics, petrophysical characteristics - and especially the importance of microporosity (< 1 mu m) - are less understood. This study presents the combination of advanced petrophysical and imaging techniques to investigate the pore network characteristics of three, common and widespread spring carbonate facies, as exposed in the Pleistocene Cakmak quarry (Denizli, Turkey): the extended Pond, the dipping crystalline Proximal Slope Facies and the draping Apron and Channel Facies deposits formed by encrustation of biological substrate. Integrating mercury injection capillary pressure, bulk and diffusion Nuclear Magnetic Resonance (NMR), NMR profiling and Brunauer-Emmett-Teller (BET) measurements with microscopy and micro-computer tomography (mu-CT), shows that NMR T-2 distributions systematically display a single group of micro-sized pore bodies, making up between 6 and 33% of the pore space (average NMR T-2 cut-off value: 62 ms). Micropore bodies are systematically located within cloudy crystal cores of granular and dendritic crystal textures in all facies. The investigated properties therefore do not reveal differences in micropore size or shape with respect to more or less biology-associated facies. The pore network of the travertine facies is distinctive in terms of (i) the percentage of microporosity, (ii) the connectivity of micropores with meso- to macropores, and (ii) the degree of heterogeneity at micro- and macroscale. Results show that an approach involving different NMR experiments provided the most complete view on the 3-D pore network especially when microporosity and connectivity are of interest.

Published

2016

3. Multiscale approach to (micro)porosity quantification in continental spring carbonate facies: Case study from the Cakmak quarry (Denizli, Turkey)

Author

De Boever, E., Foubert, A., Oligschlaeger, D., Claes, S., Soete, J., Bertier, P., and Özkul, Mehmet

Subjects

Mercury injection capillary pressures, porosity, Turkey, Quarries, Imaging techniques, Pore networks, Nuclear magnetic resonance, Microporosity, Multi-scale approaches, travertine, Micro computer tomographies, Nuclear magnetic resonance spectroscopy, pore network, Computerized tomography, Limestone, quarry, NMR, Pleistocene, Travertine Facies, facies, Denizli [Turkey], µ-CT, Nuclear magnetic resonance(NMR), Carbonation, carbonate sediment, Deposits, Brunauer emmett tellers

Abstract

Carbonate spring deposits gained renewed interest as potential contributors to subsurface reservoirs and as continental archives of environmental changes. In contrast to their fabrics, petrophysical characteristics – and especially the importance of microporosity (< 1µm) – are less understood. This study presents the combination of advanced petrophysical and imaging techniques to investigate the pore network characteristics of three, common and widespread spring carbonate facies, as exposed in the Pleistocene Cakmak quarry (Denizli, Turkey): the extended Pond, the dipping crystalline Proximal Slope Facies and the draping Apron and Channel Facies deposits formed by encrustation of biological substrate. Integrating mercury injection capillary pressure, bulk and diffusion Nuclear Magnetic Resonance (NMR), NMR profiling and Brunauer–Emmett–Teller (BET) measurements with microscopy and micro-computer tomography (µ-CT), shows that NMR T 2 distributions systematically display a single group of micro-sized pore bodies, making up between 6 and 33% of the pore space (average NMR T 2 cut-off value: 62 ms). Micropore bodies are systematically located within cloudy crystal cores of granular and dendritic crystal textures in all facies. The investigated properties therefore do not reveal differences in micropore size or shape with respect to more or less biology-associated facies. The pore network of the travertine facies is distinctive in terms of (i) the percentage of microporosity, (ii) the connectivity of micropores with meso- to macropores, and (ii) the degree of heterogeneity at micro- and macroscale. Results show that an approach involving different NMR experiments provided the most complete view on the 3-D pore network especially when microporosity and connectivity are of interest. © 2016. American Geophysical Union. All Rights Reserved.

Published

2016