Mirjam Kiczka scite author profile

Soils are the product of a complex suite of chemical, biological, and physical processes. In spite of the importance of soils for society and for sustaining life on earth, our knowledge of soil formation rates and of the influence of biological activity on mineral weathering and geochemical cycles is still limited. In this paper we provide a description of the Damma Glacier Critical Zone Observatory and present a first synthesis of our multidisciplinary studies of the 150-yr soil chronosequence. The aim of our research was to improve our understanding of ecosystem development on a barren substrate and the early evolution of soils and to evaluate the influence of biological activity on weathering rates. Soil pH, cation exchange capacity, biomass, bacterial and fungal populations, and soil organic matter show clear gradients related to soil age, in spite of the extreme heterogeneity of the ecosystem. The bulk mineralogy and inorganic geochemistry of the soils, in contrast, are independent of soil age and only in older soils (>100 yr) is incipient weathering observed, mainly as a decreasing content in albite and biotite by coincidental formation of secondary chlorites in the clay fraction. Further, we document the rapid evolution of microbial and plant munities along the chronosequence.

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Iron isotope fractionation during proton- and ligand-promoted dissolution of primary phyllosilicates

Kiczka

Wiederhold

Frommer

et al. 2010

Geochimica et Cosmochimica Acta

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Iron Isotope Fractionation during Fe Uptake and Translocation in Alpine Plants

Kiczka

Wiederhold

Kraemer

et al. 2010

Environ. Sci. Technol.

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The potential of stable Fe isotopes as a tracer for the biogeochemical Fe cycle depends on the understanding and quantification of the fractionation processes involved. Iron uptake and cycling by plants may influence Fe speciation in soils. Here, we determined the Fe isotopic composition of different plant parts including the complete root system of three alpine plant species (Oxyria digyna, Rumex scutatus, Agrostis gigantea) in a granitic glacier forefield, which allowed us, for the first time, to distinguish between uptake and in-plant fractionation processes. The overall range of fractionation was 4.5 per thousand in delta(56)Fe. Mass balance calculations demonstrated that fractionation toward lighter Fe isotopic composition occurred in two steps during uptake: (1) before active uptake, probably during mineral dissolution and (2) during selective uptake of Fe at the plasma membrane with an enrichment factor of -1.0 to -1.7 per thousand for all three species. Iron isotopes were further fractionated during remobilization from old into new plant tissue, which changed the isotopic composition of leaves and flowers over the season. This study demonstrates the potential of Fe isotopes as a new tool in plant nutrition studies but also reveals challenges for the future application of Fe isotope signatures in soil-plant environments.

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Evidence for mass-dependent isotopic fractionation of strontium in a glaciated granitic watershed

Souza¹,

Reynolds²,

Kiczka³

et al. 2010

Geochimica et Cosmochimica Acta

121

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Mirjam Kiczka

Chemical and Biological Gradients along the Damma Glacier Soil Chronosequence, Switzerland

Iron isotope fractionation during proton- and ligand-promoted dissolution of primary phyllosilicates

Iron Isotope Fractionation during Fe Uptake and Translocation in Alpine Plants

Evidence for mass-dependent isotopic fractionation of strontium in a glaciated granitic watershed

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