Experimental observations on fungal diagenesis of carbonate substrates
| Autor: | E. Keppens, Philippe Claeys, Alain Préat, Kamal Kolo |
|---|---|
| Přispěvatelé: | Earth System Sciences, Isotope Geology and Evolution of Paleo-Environmnents, Geology |
| Jazyk: | angličtina |
| Rok vydání: | 2007 |
| Předmět: |
Biomineralization
Atmospheric Science Carbonate Soil Science Mineralogy Aquatic Science engineering.material Oceanography chemistry.chemical_compound Isotopic signature Geochemistry and Petrology Earth and Planetary Sciences (miscellaneous) Earth-Surface Processes Water Science and Technology Isotope analysis Stable isotopes Ecology Whewellite Fungi Paleontology Forestry Cementation (geology) Diagenesis Geophysics chemistry Space and Planetary Science Micritisation engineering Geology Weddellite |
| Popis: | [1] Carbonate substrates (dolomites and limestones) are susceptible to fungal attack that results in significant microbial diagenesis of these substrates. In a 15-day experimental study, fungi growing in Petri dishes from airborne spores attacked petrographic thin sections and chips prepared from the dolomites of Terwagne Formation (Visean, Bocahut quarry at Avesnes-sur-Helpe, northern France) and limestones of the Morrone di Pacentro Formation (Lower Cretaceous, Italy). The analyses of the fungal material (samples of mycelia), thin sections and chips under optical microscopy, scanning electron microscope (SEM), energy dispersive X-ray (EDX), X-ray diffraction (XRD), Raman spectroscopy and stable isotopes (C and O) revealed an extensive fungally induced diagenesis. The results indicate strong diagenesis and biomineral neomorphism: neo-dolomite, glushinskite, weddellite, whewellite and possibly struvite, as well as intense substrate “de-micritization” and “micritization” with oxalates, grain bridging and cementation, open space filling, formation of intergranular and intragranular porosity, and permeability enhancement. Advanced stages of diagenesis were characterized by dissolution and replacement of original minerals by new substrates produced by fungal biomineralization. The formation of new substrates on the original attacked surfaces produced microscale stratification. Stable isotope analysis of fungal biomineralized material and of attacked and unattacked chip surfaces revealed marked differences in their isotopic signatures. The C and O isotopes of biomineralized material within the fungal mass were fractionated differently as compared to the signature measured in the original and unattacked surfaces. In sedimentary cycles, such microbially modified isotopic signature of carbonate substrates may be used to define microbial events, and consequently whether certain types of diagenesis were produced by microbial interaction. The finding of neo-dolomite formed during fungi-dolomite substrate interaction suggests the possibility of sedimentary dolomite recycling in a fungal microenvironment. The results of this experimental study confirm the significant role of fungi in reshaping carbonate substrates and forming new biominerals in the natural environment. |
| Databáze: | OpenAIRE |
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