H11F-1406
Contrasted distribution of colloidal and true dissolved phosphorus in shallow groundwaters from a small, lowland agricultural catchment
Monday, 14 December 2015
Poster Hall (Moscone South)
Sen GU1,2, Gerard Gruau1,2, Rémi Dupas3,4, Camille Rivard5, Chantal Gascuel-odoux3,4 and Jean-Marcel Dorioz6, (1)CNRS-Universite de rennes 1, UMR-Geoscience, Rennes, France, (2)CNRS, UMR 6118, Géosciences Rennes, Rennes, France, (3)Agrocampus Ouest, UMR1069, Sol Agro and hydroSystem, Rennes Cedex, France, (4)INRA Rennes, Rennes Cedex, France, (5)ESRF European Synchrotron Radiation Facility, Grenoble, France, (6)INRA, UMR CARRTEL, Thonon-les-Bains, France
Abstract:
Colloids (1~1000 nm) are major phosphorus (P) carrier phases in agricultural soils. Most studies developed so far on the role of colloids in P transport have however focused on laboratory extracted colloids with only little attention being paid to natural soil solutions. Here, we monitored P speciation in natural soil solutions along two transects in a small, agricultural catchment located in Western France, during one hydrological year. We compared the P speciation in these solutions (<0.45 µm) with that of P in lab solutions (NaCl 0.001 M) obtained from the same soil samples, using different speciation techniques, including ultrafiltration combined with inductively coupled plasma mass spectrometry (UF-ICP-MS) and XANES spectroscopy. XANES data evidenced no difference in terms of P speciation between lab extracted colloids and bulk soil samples, however revealing a strong enrichment of P in extracted colloids, thereby confirming the role of colloids as a major P carrier phase in agricultural soils. In natural soil solutions, total dissolved P concentrations (TDP) were similar in transect K and G, while molybdate reactive dissolved P (MRDP) was nearly 10 times higher in transect G than in Transect K. UF-ICP-MS data showed that the natural and lab extracted colloids consisted of a homogeneous mixture of Fe(Al)-oxides and organic matter, despite strong spatial variations of colloidal P proportion in natural waters (from 25 to 70%). Overall, transect G waters showed high proportions of truly-dissolved MRDP (up to 65%), waters in Transect K being richer in colloidal P and truly-dissolved organic P (OP). Lab extractions, however, did not reveal the same difference in P speciation, all the extracts being dominated by colloidal P and MRDP in roughly the same proportions. So far, the cause of this difference is not clearly identified. Though confirming the important role of colloids as a major P carrier phase in agricultural soils, this study indicates that natural soil solutions and lab extracts may yield different results regarding P speciation in soils, and that care should be exercised in extrapolating lab data to field situation.