Autotrophic denitrification supported by biotite dissolution in crystalline aquifers (1): New insights from short-term batch experiments

We investigate denitrification mechanisms through batch experiments using crushed rock and groundwater from a granitic aquifer subject to long term pumping (Ploemeur, France). Except for sterilized experiments, extensive denitrification reaction induces NO3 decreases ranging from 0.3 to 0.6mmol/L. C...

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Bibliographic Details
Published in:The Science of the total environment 2018-04, Vol.619-620, p.842-853
Main Authors: Aquilina, Luc, Roques, Clément, Boisson, Alexandre, Vergnaud-Ayraud, Virginie, Labasque, Thierry, Pauwels, Hélène, Pételet-Giraud, Emmanuelle, Pettenati, Marie, Dufresne, Alexis, Bethencourt, Lorine, Bour, Olivier
Format: Article
Language:English
Subjects:
Batch experiment
Denitrification mechanism
Earth Sciences
Fractured aquifers
Geochemistry
Groundwater resource
Hydrology
Sciences of the Universe
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Summary:We investigate denitrification mechanisms through batch experiments using crushed rock and groundwater from a granitic aquifer subject to long term pumping (Ploemeur, France). Except for sterilized experiments, extensive denitrification reaction induces NO3 decreases ranging from 0.3 to 0.6mmol/L. Carbon concentrations, either organic or inorganic, remain relatively stable and do not document potential heterotrophic denitrification. Batch experiments show a clear effect of mineral dissolution which is documented through cation (K, Na, Ca) and Fluoride production. These productions are tightly related to denitrification progress during the experiment. Conversely, limited amounts of SO4, systematically lower than autotrophic denitrification coupled to sulfur oxidation stoichiometry, are produced during the experiments which indicates that sulfur oxidation is not likely even when pyrite is added to the experiments. Analysis of cation ratios, both in isolated minerals of the granite and within water of the batch, allow the mineral dissolution during the experiments to be quantified. Using cation ratios, we show that batch experiments are characterized mainly by biotite dissolution. As biotite contains 21 to 30% of Fe and 0.3 to 1.7% of F, it constitutes a potential source for these two elements. Denitrification could be attributed to the oxidation of Fe(II) contained in biotite. We computed the amount of K and F produced through biotite dissolution when entirely attributing denitrification to biotite dissolution. Computed amounts show that this process may account for the observed K and F produced. We interpret these results as the development of microbial activity which induces mineral dissolution in order to uptake Fe(II) which is used for denitrification. Although pyrite is probably available, SO4 and cation measurements favor a large biotite dissolution reaction which could account for all the observed Fe production. Chemical composition of groundwater produced from the Ploemeur site indicates similar denitrification processes although original composition shows mainly plagioclase dissolution. [Display omitted] •We investigate autotrophic denitrification mechanisms through batch experiments.•We show that denitrification is mainly attributed to the oxidation of Fe(II) in biotite.•Nitrate reduction coupled to the oxidation of iron from silicates plays a key role in the Nitrogen cycle.
ISSN:0048-9697
1879-1026
DOI:10.1016/j.scitotenv.2017.11.079