In
wetland-adapted plants, such as rice, it is typically root apexes,
sites of rapid entry for water/nutrients, where radial oxygen losses
(ROLs) are highest. Nutrient/toxic metal uptake therefore largely
occurs through oxidized zones and pH microgradients. However, the
processes controlling the acquisition of trace elements in rice have
been difficult to explore experimentally because of a lack of techniques
for simultaneously measuring labile trace elements and O2/pH. Here, we use new diffusive gradients in thin films (DGT)/planar
optode sandwich sensors deployed in situ on rice
roots to demonstrate a new geochemical niche of greatly enhanced As,
Pb, and Fe(II) mobilization into solution immediately adjacent to
the root tips characterized by O2 enrichment and low pH.
Fe(II) mobilization was congruent to that of the peripheral edge of
the aerobic root zone, demonstrating that the Fe(II) mobilization
maximum only developed in a narrow O2 range as the oxidation
front penetrates the reducing soil. The Fe flux to the DGT resin at
the root apexes was 3-fold higher than the anaerobic bulk soil and
27 times greater than the aerobic rooting zone. These results provide
new evidence for the importance of coupled diffusion and oxidation
of Fe in modulating trace metal solubilization, dispersion, and plant
uptake.
A numerical model of the transport and dynamics of metal complexes in the resin and gel layers of a DGT (diffusive gradients in thin films) device was developed and used to investigate how the chelating resin and metal-ligand complexes in solution affect metal uptake. Decreasing the stability constant or concentration of the binding resin increases the competition for free metal ions by ligands in solution, lowering the rate of mass uptake. Such effects would be rarely observed for moderately or strongly binding resins (K> 10(12)), including Chelex, which out-compete labile ligands in solution. With weakly binding resins, strongly bound solution complexes can diffuse into the resin layer before a measurable amount of dissociation occurs, such that concentrations of bound metal at the rear and front surfaces of the resin layer are equal. With more strongly binding resins, metal mainly binds to the front surface of the resin. Only complexes with the largest binding constants penetrate the gel layer containing Chelex, buttheir lack of lability means thatthe DGT sensitivity to the complex is, in any case, very low. The slow diffusion of complexes, such as those of fulvic acids, which increases the time required to establish steady state, compromises the use of the simple DGT equation. Errors are negligible for 24 h deployments, when diffusive layer thicknesses are less than 1 mm, but 3 day deployments are required to ensure accuracy with 2.4 mm thick layers. The extent to which the commonly used equation, that accounts for the concentration and diffusion of metal-complex species, overestimates DGT uptake if the rate of dissociation is slow, was estimated.
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