Elemental Composition of Natural Nanoparticles and Fine Colloids in European Forest Stream Waters and Their Role as Phosphorus Carriers

Gottselig, Nina; Amelung, Wulf; Kirchner, James W.; Bol, Roland; Eugster, Werner; Granger, Steven J.; Hernández-Crespo, Carmen; Herrmann, Falko F. H.; Keizer, Jan Jacob; Korkiakoski, Mika; Laudon, Hjalmar; Lehner, Irene; Löfgren, Stefan; Lohila, Annalea; Macleod, Christopher; Mölder, Meelis; Müller, Christoph; Nasta, Paolo; Nischwitz, Volker; Paul‐Limoges, Eugénie; Pierret, M. C.; Pilegaard, Kim; Romano, Nunzio; Sebastià, Maria‐Teresa; Stähli, Manfred; Voltz, Marc; Vereecken, Harry; Siemens, Jan; Klumpp, Erwin

doi:10.1002/2017gb005657

Cited by 57 publications

(39 citation statements)

References 56 publications

(76 reference statements)

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“…This was attributed to the greater contents of Fe and Al in acidic soil than in alkaline soil, and that the presence of Al and Fe oxides may have enhanced the adsorption of P and stabilization of soil aggregates [15,31,63]. Al and Fe oxides have been recognized as important carriers of P coll [64][65][66][67].…”

Section: Colloidal P Content In Aggregatesmentioning

confidence: 99%

“…We observed that the CR value of (silt + clay)-sized particles was larger than that of aggregates of other sizes, while the CR of large macroaggregates was the lowest in most soils, indicating that the (silt + clay)sized particles contribute more to the P coll loss potential, while macroaggregates immobilized soil P coll . Colloidal P is highly bound to Fe and Al on the surface of macroaggregates [15,68], enabling the formation of a stable composite structure that can resist the shear force of pore flow [64,65]. Similarly, soil macroaggregates can increase the adsorption of P coll on the surface and reduce its mobility [26].…”

Section: Loss Potential Of Colloidal P In Aggregatesmentioning

confidence: 99%

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Enhanced soil aggregate stability limits colloidal phosphorus loss potentials in agricultural systems

Jin

et al. 2020

Environ Sci Eur

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Background: Colloid-facilitated phosphorus (P) transport is recognized as an important pathway for the loss of soil P in agricultural systems; however, information regarding soil aggregate-associated colloidal P (P coll ) is lacking. To elucidate the effects of aggregate size on the potential loss of P coll in agricultural systems, soils (0-20 cm depth) from six land-use types were sampled in the Zhejiang Province in the Yangtze River Delta region, China. The aggregate size fractions (2-8 mm, 0.26-2 mm, 0.053-0.26 mm and < 0.053 mm) were separated using the wet sieving method. Colloidal P and other soil parameters in aggregates were analyzed. Results:Our study demonstrated that 0.26-2 mm small macroaggregates had the highest total P (TP) content. In acidic soils, the highest P coll content was observed in the 0.26-to 2-mm-sized aggregates, while the lowest was reported in the < 0.053 mm (silt + clay)-sized particles, the opposite of that revealed in alkaline and neutral soils. Paddy soils contained less P coll than other land-use types. The proportion of P coll in total dissolved P (TDP) was dominated by < 0.053 mm (silt + clay)-sized particles. Aggregate size strongly influenced the loss potential of P coll in paddy soils, where P coll contributed up to 83% TDP in the silt + clay-sized particles. The P coll content was positively correlated with TP, Al, Fe, and the mean weight diameter. Aggregate-associated total carbon (TC), total nitrogen (TN), C/P, and C/N had significant negative effects on the contribution of P coll to potential soil P loss. The P coll content of the aggregates was controlled by the aggregate-associated TP and Al content, as well as the soil pH value. The potential loss of P coll from aggregates was controlled by its organic matter content. Conclusion:We concluded that management practices that increase soil aggregate stability or its organic carbon content will limit P coll loss in agricultural systems.

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Section: Colloidal P Content In Aggregatesmentioning

confidence: 99%

Section: Loss Potential Of Colloidal P In Aggregatesmentioning

confidence: 99%

Enhanced soil aggregate stability limits colloidal phosphorus loss potentials in agricultural systems

Jin

et al. 2020

Environ Sci Eur

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“…Locating and apportionment of the sources and fluxes of the dissolved vs. collodial P conveyed by rivers in landscapes remains a longstanding and fundamental challenge for catchment scientists (see McClain et al, 2003;Bol et al, 2016;Gottselig et al, 2017b;Missong et al, 2018), with major implications for land management and nutrient pollution mitigation strategies. Colloidal P is characterized as dissolved P in most routine water quality monitoring programs (Gottselig et al, 2017a), however, it is believed to have reduced bioavailability compared to the truly dissolved P (Baken et al, 2014).…”

Section: Difficulties In Predictions Of Dissolved/colloidal/particulamentioning

confidence: 99%

Challenges of Reducing Phosphorus Based Water Eutrophication in the Agricultural Landscapes of Northwest Europe

et al. 2018

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“…In comparison, the origin of the finest inorganic colloidal fraction transported by rivers remains far less constrained and understood. This question is of particular importance because colloidal nanoparticles have a substantial surface area, and typically serve as sinks and/or sources for trace metals, nutrients and pollutants in the natural environment (e.g., Hill and Aplin, 2001;Pokrovsky and Schott, 2002;Kulaksiz and Bau, 2013;Trostle et al, 2016;Gottselig et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Preferential Riverine Export of Fine Volcanogenic Particles to the Southeast Australian Margin

et al. 2020

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We report on rare earth element and neodymium isotopic compositions in a series of grain-size fractions separated from river suspended matter in the Murray-Darling Basin (MDB) and a nearby marine sediment core (MD03-2607) offshore southeastern Australia. This source-to-sink approach was used to further investigate the extent to which sediment sorting may control the geochemistry of suspended loads in rivers, and to provide constraints on the source of the detrital sediment material exported to the ocean. Our results provide further compelling evidence that significant sizedependent geochemical decoupling can occur in river systems, accounting here for Nd isotopic (ε Nd) differences of up to eight epsilon-units between silt (>25 µm) and colloidal (0.2−0.006 µm; 0.006−0.003 µm) fractions. All suspended particulate samples from the River Murray watershed display a trend toward more radiogenic (higher ε Nd) Nd signatures with decreasing grain-size, in addition to differing REE signatures, which collectively point toward a preferential volcanogenic origin for the fine-grained inorganic particles transported by MDB rivers. Furthermore, we show that the same river-borne volcanogenic material dominates in the fine-grained detrital fractions extracted from core MD03-2607 at the southeastern Australian margin; a finding corroborated by REE signatures in a series of copepod fecal pellet separates from the same core. Collectively, our results suggest that river sediment discharge is accompanied by preferential export of fine-grained volcanogenic particles to the ocean. This potential source of bioavailable trace metals and nutrients in ocean surface waters could impact marine productivity.

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Elemental Composition of Natural Nanoparticles and Fine Colloids in European Forest Stream Waters and Their Role as Phosphorus Carriers

Cited by 57 publications

References 56 publications

Enhanced soil aggregate stability limits colloidal phosphorus loss potentials in agricultural systems

Enhanced soil aggregate stability limits colloidal phosphorus loss potentials in agricultural systems

Challenges of Reducing Phosphorus Based Water Eutrophication in the Agricultural Landscapes of Northwest Europe

Preferential Riverine Export of Fine Volcanogenic Particles to the Southeast Australian Margin

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