Size and charge constraints in microaggregation: Model experiments with mineral particle size fractions

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  • Martin Luther University Halle-Wittenberg
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Original languageEnglish
Pages (from-to)29-40
Number of pages12
JournalApplied clay science
Volume170
Early online date23 Jan 2019
Publication statusPublished - 15 Mar 2019

Abstract

In natural soil systems the mass ratio of clay minerals and Fe oxides is decisive for aggregate formation and stability but little information exists on the importance of size constrains in microaggregation. Therefore, we determined the aggregation kinetics of mono- and dual-mineral mixtures at pH 6 by dynamic light scattering, using three size fractions of model minerals (goethite and illite). Aggregates were characterized by scanning electron microscopy (SEM), and measured for zeta potential (ζ), surface chemical composition by X-ray photoelectron spectroscopy (XPS), and specific surface area (SSA). Destabilization experiments using sonication revealed the stability against dispersion. Aggregation occurred in all homoaggregation experiments, particularly for fine illite (<0.2 μm). Illite-goethite heteroaggregation experiments revealed a broad range of aggregation with increasing goethite additions (0–90 %) for fine illite and a narrow one for medium and coarse illite (0–15 %). Maximal aggregation typically occurred at the point of zero charge (pzc) of respective mineral mixtures. Surface chemical analysis, N 2 gas adsorption, and SEM showed that the illite surfaces were largely covered by goethite layers and clusters. Illite-goethite heteroaggregates were most stable at their pzc, whereas homoaggregates were generally less stable. Our study suggests a primary role of the <0.2-μm clay fraction in the formation of stable clay-oxide microaggregates.

Keywords

    Aggregate stability, Aggregation, Goethite, Illite, Particle size fractions, XPS, Zeta potential

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Cite this

Size and charge constraints in microaggregation: Model experiments with mineral particle size fractions. / Dultz, Stefan; Woche, Susanne Karoline; Mikutta, Robert et al.
In: Applied clay science, Vol. 170, 15.03.2019, p. 29-40.

Research output: Contribution to journalArticleResearchpeer review

Dultz S, Woche SK, Mikutta R, Schrapel M, Guggenberger G. Size and charge constraints in microaggregation: Model experiments with mineral particle size fractions. Applied clay science. 2019 Mar 15;170:29-40. Epub 2019 Jan 23. doi: 10.1016/j.clay.2019.01.002
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abstract = " In natural soil systems the mass ratio of clay minerals and Fe oxides is decisive for aggregate formation and stability but little information exists on the importance of size constrains in microaggregation. Therefore, we determined the aggregation kinetics of mono- and dual-mineral mixtures at pH 6 by dynamic light scattering, using three size fractions of model minerals (goethite and illite). Aggregates were characterized by scanning electron microscopy (SEM), and measured for zeta potential (ζ), surface chemical composition by X-ray photoelectron spectroscopy (XPS), and specific surface area (SSA). Destabilization experiments using sonication revealed the stability against dispersion. Aggregation occurred in all homoaggregation experiments, particularly for fine illite (<0.2 μm). Illite-goethite heteroaggregation experiments revealed a broad range of aggregation with increasing goethite additions (0–90 %) for fine illite and a narrow one for medium and coarse illite (0–15 %). Maximal aggregation typically occurred at the point of zero charge (pzc) of respective mineral mixtures. Surface chemical analysis, N 2 gas adsorption, and SEM showed that the illite surfaces were largely covered by goethite layers and clusters. Illite-goethite heteroaggregates were most stable at their pzc, whereas homoaggregates were generally less stable. Our study suggests a primary role of the <0.2-μm clay fraction in the formation of stable clay-oxide microaggregates. ",
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author = "Stefan Dultz and Woche, {Susanne Karoline} and Robert Mikutta and Martin Schrapel and Georg Guggenberger",
note = "Funding information: We kindly acknowledge financial support by the Deutsche Forschungsgemeinschaft within the framework of the research unit “MAD Soil - Microaggregates: Formation and turnover of the structural building blocks of soils” ( DFG RU 2179 ).",
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T2 - Model experiments with mineral particle size fractions

AU - Dultz, Stefan

AU - Woche, Susanne Karoline

AU - Mikutta, Robert

AU - Schrapel, Martin

AU - Guggenberger, Georg

N1 - Funding information: We kindly acknowledge financial support by the Deutsche Forschungsgemeinschaft within the framework of the research unit “MAD Soil - Microaggregates: Formation and turnover of the structural building blocks of soils” ( DFG RU 2179 ).

PY - 2019/3/15

Y1 - 2019/3/15

N2 - In natural soil systems the mass ratio of clay minerals and Fe oxides is decisive for aggregate formation and stability but little information exists on the importance of size constrains in microaggregation. Therefore, we determined the aggregation kinetics of mono- and dual-mineral mixtures at pH 6 by dynamic light scattering, using three size fractions of model minerals (goethite and illite). Aggregates were characterized by scanning electron microscopy (SEM), and measured for zeta potential (ζ), surface chemical composition by X-ray photoelectron spectroscopy (XPS), and specific surface area (SSA). Destabilization experiments using sonication revealed the stability against dispersion. Aggregation occurred in all homoaggregation experiments, particularly for fine illite (<0.2 μm). Illite-goethite heteroaggregation experiments revealed a broad range of aggregation with increasing goethite additions (0–90 %) for fine illite and a narrow one for medium and coarse illite (0–15 %). Maximal aggregation typically occurred at the point of zero charge (pzc) of respective mineral mixtures. Surface chemical analysis, N 2 gas adsorption, and SEM showed that the illite surfaces were largely covered by goethite layers and clusters. Illite-goethite heteroaggregates were most stable at their pzc, whereas homoaggregates were generally less stable. Our study suggests a primary role of the <0.2-μm clay fraction in the formation of stable clay-oxide microaggregates.

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