Mineral colloids mediate organic carbon accumulation in a temperate forest Spodosol: depth-wise changes in pore water chemistry

Mineral colloids mediate organic carbon accumulation in a temperate forest Spodosol depth-wise changes in pore water chemistry

Mobile submicron mineral phases within soil pore waters are presumed to play a major role in the transport and availability of organic carbon (OC) in subsurface horizons. This work reports on the composition of the < 0.45 lm and 0.45–1.2 μm size fractions of extracted soil pore waters from horizo...

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Bibliographic Details
Published in:Biogeochemistry Vol. 141; no. 1; pp. 75 - 94
Main Authors: Bazilevskaya, Ekaterina, Archibald, Douglas D., Martínez, Carmen Enid
Format: Journal Article
Language:English
Published: Cham Springer Science + Business Media 01-10-2018
Springer International Publishing
Springer Nature B.V
Subjects:
Accumulation
Aluminum
Analytical methods
Atomic properties
Availability
Biogeosciences
Carbon
Chemical equilibrium
Colloids
Composition
Crystallites
Crystals
Earth and Environmental Science
Earth Sciences
Ecosystems
Electron microscopy
Environmental Chemistry
Immobilization
Infrared spectroscopy
Iron
Life Sciences
Metal compounds
Metal concentrations
Metals
Modelling
Organic carbon
Organic chemistry
Organic matter
ORIGINAL PAPERS
pH effects
Pore water
Ratios
Silica
Silicon dioxide
Soil
Soil conditions
Soil horizons
Soils
Structures
Temperate forests
Transmission electron microscopy
Transport
Water chemistry
Water depth
Soil
Organic carbon
Spectroscopy
Microscopy
Soil pore waters
Colloids
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Summary:Mobile submicron mineral phases within soil pore waters are presumed to play a major role in the transport and availability of organic carbon (OC) in subsurface horizons. This work reports on the composition of the < 0.45 lm and 0.45–1.2 μm size fractions of extracted soil pore waters from horizons of a well-drained-Spodosol-soil to reveal conditions favorable for carbon mobility and accumulation. These operationally defined quantities are abbreviated SF-S (size fraction small) and SF-L (size fraction large) to identify the < 0.45 µm and the 0.45–1.2 µm size fraction filtrates, respectively. It is found that in the SF-S fraction, OC mass concentrations are more than 30–50 times higher than metal (M = Fe + Al) mass concentrations in all Spodosol horizons, with metal-to-carbon (M/C) atomic ratios of 0.15–0.03. Chemical equilibrium modeling calculations estimate < 95% of the total Fe and Al in SF-S are complexed with OC in all Spodosol horizons. In contrast with the SF-S, the SF-L had much greater OC concentrations and even lower M/C (< 0.01), except in the Bh horizon (M/C = 0.05). In Bh, major accumulation of organic matter occurred above the lesser-accumulating Bhs, the latter having higher pH, but much lower OC in all forms (soil, colloidal). Infrared spectroscopy indicates the SF-L fraction of soil pore waters contains both organic and inorganic constituents, including amorphous silica, the second-most abundant component after OC. Mineral-organic associations such as mineral crystallites embedded in OC are observed in the SF-L fraction by transmission electron microscopy (TEM). Transmission electron microscopy also reveal carbon-rich amorphous structures containing traces of Fe, Al and Si, and small (~ 100 nm) spherical amorphous SiO₂ particles. These observations provide support for the main mechanism of OC accumulation in Spodosols being the downward movement of colloids (organic, OC-sorbed mineral and organo-mineral), followed by colloid immobilization due to a combination of increases in pH and M/C ratio. The occurrence of these three types of colloidal structures in pore waters seems to depend on the pH and the relative supply of OC and Fe + Al to pore waters. Similar colloidal structures might also contribute to the transport and availability of OC in subsurface horizons of soils that range in the accumulation of organic and organometallic compounds, that is, in the expression of spodic properties.
ISSN:0168-2563
1573-515X
DOI:10.1007/s10533-018-0504-4