Journal
GEODERMA
Volume 221, Issue -, Pages 139-145Publisher
ELSEVIER
DOI: 10.1016/j.geoderma.2014.01.012
Keywords
Hawaii; Soil organic matter; Anoxia; Iron reduction; pH; Asymmetric flow field-flow fractionation
Categories
Funding
- United States Department of Energy (DOE) [DE-FC09-0751222506]
- Savannah River National Lab, Area Closure Projects
- United States Department of Agriculture (USDA)
- AFRI [2009-65107-05830]
- National Science Foundation (NSF) Geobiology and Low-temperature Geochemistry [EAR-1053470]
- Directorate For Geosciences
- Division Of Earth Sciences [1053470] Funding Source: National Science Foundation
- Directorate For Geosciences
- Division Of Earth Sciences [1053406] Funding Source: National Science Foundation
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The transport of organic carbon (C) to deep mineral horizons in soils can lead to long-term C stabilization. In basaltic soils, C associations with short-range-ordered (SRO) minerals often lead to colloid-sized aggregates that can be dispersed and mobilized by changes in soil solution chemistry. In the montane forest region of Hawaii, basaltic soils are exposed to high rainfall and anoxic conditions that facilitate ferric (Fe-III) (oxyhydr)oxide reduction. We explored the potential of iron (Fe)-reducing conditions to mobilize C by exposing the surface mineral horizons of three soils from the Island of Hawai'i (aged 03, 20, and 350 ky) to 21 days of anoxic incubation in 1:10 soil slurries. Mobilized C was quantified by fractionating the slurries into three particle-size classes (<430 nm,<60 nm,<23 nm approximate to 10 kDa). In all three soils, we found Fe reduction (maximum Fe2+ (aq) concentration approximate to 17.7 +/- 1.9 mmol kg(-1) soil) resulted in similar to 500% and similar to 700% increase of C in the 23-430 nm, and <23 nm size fractions, respectively. In addition, Fe reduction increased solution ionic strength by 127 mu S cm(-1) and generated hydroxyl ions sufficient to increase the slurry pH by one unit. We compared this to C mobilized from the slurries during a 2-h oxic incubation across a similar range of pH and ionic strength and found smaller amounts of dissolved (<23 nm) and colloidal (23-430 nm) C were mobilized relative to the Fe reduction treatments (p < 0.05). In particular, C associated with the largest particles (60-430 nm) was dispersed almost exclusively during the Fe reduction experiments, suggesting that it had been bound to Feoxide phases. Our experiments suggest that colloidal dispersion during Fe-reducing conditions mobilizes high concentrations of C, which may explain how C migrates to deep mineral horizons in redox dynamic soils. (C) 2014 Elsevier B.V. All rights reserved.
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