In many forest ecosystems, plant-available
pools of Mg, Ca, and
K are assumed to be stored in the soil as exchangeable cations adsorbed
on the cation exchange complex (exchangeable pools). However, between
soil minerals and exchangeable cations exists a gradient of Mg, Ca,
and K storage forms that have not been fully characterized and may
play an important role in plant nutrition and biogeochemical cycles.
We hypothesize that sources of Mg, Ca, and K in the soil other than
the conventionally measured exchangeable pools are plant-available
on very short time scales (<1 day). In the present study, we developed
and applied an isotopic dilution technique using the stable isotopes 26Mg, 44Ca, and 41K to trace and quantify
the pools of Mg, Ca, and K (isotopically exchangeable pools) in the
soil of a hardwood forest that contribute directly to equilibrium
processes between the soil water and the soil. We characterize the
equilibrium between the soil and soil solution using both a batch
approach and a flow-through approach in order (i) to develop and determine
the best routine method to measure the isotopically exchangeable pools
and (ii) to further the characterization of the forms of storage of
Mg, Ca, and K in the isotopically exchangeable pools. We first show
that the flow-through reactor approach (equilibrium in unsaturated
soil columns) is the most adequate to measure the isotopically exchangeable
pools with the fewest equilibrium disturbances. We then show that
isotopically exchangeable pools of Mg, Ca, and K are greater than
traditionally measured exchangeable pools. The isotopically exchangeable
pools of Mg, Ca, and K are mainly composed of traditionally measured
exchangeable pools (88.8–98.5% for Mg, 74.7–97.7% for
Ca, and 68.7–77.1% for K) but are also composed of pools extracted
with the Tamm reagent (oxalic acid, pH 3) and nitric acid (1 mol·L–1): 1.5–11.2% for Mg, 2.3–25.3% for Ca,
and 22.9–31.3% for K. Storage forms of Mg, Ca, and K in the
isotopically exchangeable pool could include chelation with soil organic
matter, retention on soil aluminum and iron oxides and hydroxides
through phosphate and/or organic acid bridges and site-specific adsorption.
The isotopic dilution method is a relevant tool to quantify the plant-available
pools of Mg, Ca, and K on short time scales (source and sink pools)
and is a very promising approach to characterize and quantify the
processes responsible for the depletion and/or replenishment of these
pools over longer time scales.
