Can Fe isotope fractionations trace the pedogenetic mechanisms involved in podzolization?

Fekiacova, Zuzana; Vermeire, Marie-Liesse; Bechon, Loick; Cornélis, Jean-Thomas; Cornu, Sophie

doi:10.1016/j.geoderma.2017.02.020

Cited by 15 publications

(12 citation statements)

References 52 publications

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“…The processes of mineral weathering, Al/Fe complexation and mobilization as well as leaching of alkaline and alkaline-earth cations rapidly TABLE 2 | C fractions: total (C T ), Stable (C S ), recalcitrant (C R ), mineral-protected (C MP ), oxidizable (C O ), bulk soil SOM C T /N T ratio (values are given ± one standard deviation); soil respiration rates (slope of the cumulative CO 2 emission with time, calculated by linear regression, and associated R²-values), and soil respiration rates normalized by the total SOC content (=SOM biodegradability). occur, in less than 60 years, i.e., between P3-270 years and P4-330 years (Vermeire et al, 2016;Fekiacova et al, 2017). Such a timing for incipient podzolization is in agreement with several studies reviewed in Sauer et al (2008), revealing the formation of a bleached E horizon after about 200-500 years.…”

Section: Acidification and Accumulation Of Secondary Mineral Phasessupporting

confidence: 91%

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Vermeire

Cornélis

Ranst

et al. 2018

Front. Environ. Sci.

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Section: Acidification and Accumulation Of Secondary Mineral Phasessupporting

confidence: 91%

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Vermeire

Cornélis

Ranst

et al. 2018

Front. Environ. Sci.

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“…More precisely, Fe isotopes in soils are sensitive to redox processes, to weathering processes and the formation of Fe-oxides, and to the formation of Fe-organic complexes. Light Fe isotopes are often enriched in soils containing secondary Fe phases (e.g., Wiederhold et al, 2007b;Poitrasson et al, 2008;Guelke et al, 2010;Kiczka et al, 2011;Yesavage et al, 2012;Liu et al, 2014;Fekiacova et al, 2017). This enrichment can be explained by the quantitative precipitation of light Fe-oxyhydroxides from light Fe isotopes preferentially released by proton-promoted mineral weathering (Chapman et al, 2009;Kiczka et al, 2010a), reductive mineral dissolution (e.g., Wiederhold et al, 2006Wiederhold et al, , 2007aWiederhold et al, , 2007b, and ligand-controlled mineral dissolution (Brantley et al, 2001(Brantley et al, , 2004Wiederhold et al, 2006Wiederhold et al, , 2007bBuss et al, 2010).…”

Section: Introductionmentioning

confidence: 99%

Iron and silicon isotope behaviour accompanying weathering in Icelandic soils, and the implications for iron export from peatlands

Opfergelt

Williams

Cornélis

et al. 2017

Geochimica et Cosmochimica Acta

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Incipient warming of peatlands at high latitudes is expected to modify soil drainage and hence the redox conditions, which has implications for Fe export from soils. This study uses Fe isotopes to assess the processes controlling Fe export in a range of Icelandic soils including peat soils derived from the same parent basalt, where Fe isotope variations principally reflect differences in weathering and drainage. In poorly weathered, well-drained soils (non-peat soils), the limited Fe isotope fractionation in soil solutions relative to the bulk soil (D 57 Fe solution-soil = À0.11 ± 0.12‰) is attributed to proton-promoted mineral dissolution. In the more weathered poorly drained soils (peat soils), the soil solutions are usually lighter than the bulk soil (D 57 Fe solution-soil = À0.41 ± 0.32‰), which indicates that Fe has been mobilised by reductive mineral dissolution and/or ligand-controlled dissolution. The results highlight the presence of Fe-organic complexes in solution in anoxic conditions. An additional constraint on soil weathering is provided by Si isotopes. The Si isotope composition of the soil solutions relative to the soil (D 30 Si solution-soil = 0.92 ± 0.26‰) generally reflects the incorporation of light Si isotopes in secondary aluminosilicates. Under anoxic conditions in peat soils, the largest Si isotope fractionation in soil solutions relative to the bulk soil is observed (D 30 Si solution-soil = 1.63 ± 0.40‰) and attributed to the cumulative contribution of secondary clay minerals and amorphous silica precipitation. Si supersaturation in solution with respect to amorphous silica is reached upon freezing when Al availability to form aluminosilicates is limited by the affinity of Al for metal-organic complexes. Therefore, the precipitation of amorphous silica in peat soils indirectly supports the formation of metal-organic complexes in poorly drained soils. These observations highlight that in a scenario of decreasing soil drainage with warming high latitude peatlands, Fe export from soils as Fe-organic complexes will increase, which in turn has implications for Fe transport in rivers, and ultimately the delivery of Fe to the oceans.

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“…The differences between summer and late autumn are driven by regional changes of the groundwater table, while data from spring show a wide range of Fe isotope values, which might be ascribed to more local differences. For the formation of a distinctly negative Fe isotope ratio, soil formation processes are necessary. ,, Excluding the organic top layer, the upper soil horizons are dominated by mineral dissolution by organic acids and light Fe(II) aq is released to the solution, , leaving the soil enriched in heavy Fe isotopes . Vertical percolation to underlying horizons results in a light Fe isotope ratio in soil solution and groundwater. ,− On the other hand, the Fe isotope ratio of the solid phase is more positive. ,− An in situ field experiment showed abiotic fractionation of Fe isotopes due to adsorption of Fe(II) aq onto newly formed Fe(III)(oxy)hydroxides .…”

Section: Resultsmentioning

confidence: 99%

“…Oxygen-rich water was injected into reduced Fe(II) aq -rich groundwater and resulted in a very light groundwater component (down to −2.60‰). Several studies have shown that dissolved Fe(II) aq is partly oxidized and precipitates during transport through the unsaturated zone of soils, causing migrating soil water Fe to be enriched in the light Fe isotope. ,,,,,,− …”

Section: Resultsmentioning

confidence: 99%

“…In nature, redox changes are the main driver behind Fe isotope fractionation, as the reduced Fe(II) aq species tend to have lower 56 Fe/ 54 Fe ratios compared with Fe(III) aq compounds. , A variety of Fe isotope values (δ 56 Fe relative to IRMM-014) have been reported for solid fractions of soils (−0.6 to 1.2‰), − soil solutions (−4.9 to 0.9‰), − and organic-rich rivers (−1.2 to 1.2‰). − The Fe isotope ratios in streams reflect the Fe isotope ratios in soils and how the redox conditions vary within the catchment . Besides the ferrous/ferric iron system, many sulfur and nitrogen compounds will be affected by climate induced redox changes.…”

Section: Introductionmentioning

confidence: 99%

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Seasonal Variations of Redox State in Hemiboreal Soils Indicated by Changes of δ⁵⁶Fe, Sulfate, and Nitrate in Headwater Streams

Conrad

Löfgren

Bauer

et al. 2019

ACS Earth Space Chem.

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During recent decades, much focus has been put on the iron (Fe) isotope ratios in soils, rivers, and oceans, while studies on the variation in headwater streams are scarce.Here we assess seasonal water chemical data from 104 hemiboreal headwater streams. Between summer and late autumn, decreasing Fe concentrations and simultaneously increasing sulfate and nitrate concentrations suggest a shift from reduced to oxidized conditions in the soils along the main groundwater flow paths. Fe isotope data, obtained from a subpopulation of 16 streams, show low δ 56 Fe ratios during summer drought, indicating an important influx of reduced groundwater to the streams with primarily Fe(II) as an important Fe source. In total, the δ 56 Fe data ranged between −0.8 ± 0.1 and 1.8 ± 0.1‰ with the lowest values in summer and maximum δ 56 Fe ratios in late autumn or spring, indicating an influx of more oxidized, less Fe(II) rich groundwater during those seasons. Local differences in δ 56 Fe ratios between the headwater streams, seemed to be driven by the different soil redox status of the catchments. The streams with the lowest δ 56 Fe ratios during summer are characterized by a small share (4.4 ± 6.6%) of wetlands, indicating discharge of reduced groundwater from mainly anoxic, moist, organic-rich mineral soils during drought. Relatively high total organic carbon (TOC) concentrations (2.4 ± 1.1 mM) and low pH (5.2 ± 0.8) may have restricted efficient Fe(II) oxidation in streamwater especially during the late autumn survey. Our results from hemiboreal headwater streams reveal the importance of climatic, pedogenic, and land cover-derived controls on the provenance of stream Fe loads that is likely broadly applicable to similar streams elsewhere.

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Can Fe isotope fractionations trace the pedogenetic mechanisms involved in podzolization?

Cited by 15 publications

References 52 publications

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Iron and silicon isotope behaviour accompanying weathering in Icelandic soils, and the implications for iron export from peatlands

Seasonal Variations of Redox State in Hemiboreal Soils Indicated by Changes of δ⁵⁶Fe, Sulfate, and Nitrate in Headwater Streams

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Can Fe isotope fractionations trace the pedogenetic mechanisms involved in podzolization?

Cited by 15 publications

References 52 publications

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Soil Microbial Populations Shift as Processes Protecting Organic Matter Change During Podzolization

Iron and silicon isotope behaviour accompanying weathering in Icelandic soils, and the implications for iron export from peatlands

Seasonal Variations of Redox State in Hemiboreal Soils Indicated by Changes of δ56Fe, Sulfate, and Nitrate in Headwater Streams

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Seasonal Variations of Redox State in Hemiboreal Soils Indicated by Changes of δ⁵⁶Fe, Sulfate, and Nitrate in Headwater Streams