For convenience, soil samples are often dried before storage and experiment
al use, However, the literature offers examples of drying that results in c
hanges in pH, solubility of organic matter, and dissolution rates of Al. In
this study we examined the solubility of Al and Si in fresh soil and in so
il that had been dried or deep-frozen. Five Spodosol B horizon soils were s
ubjected to batch titrations, where portions of each soil were equilibrated
with solutions with varying concentrations of acid or base added, Extracti
ons with acid oxalate and Na pyrophosphate indicated the presence of imogol
ite-type materials (ITM) in three of the soils. In the other two soils most
secondary solid-phase Al was associated with humic substances, Deep-freezi
ng did not significantly change pH nor the concentration of Al or Si as com
pared with fresh soil, Drying, on the other hand, yielded pH increases of u
p to 0.3 units at a given addition of acid or base, whereas Al3+ changed on
ly slightly, implying a higher Al solubility in all of the soils, Furthermo
re, dissolved silica increased by up to 200% after drying, except in a soil
that almost completely larked oxalate-extractable Si. We suggest that dryi
ng enhanced the dissolution of ITM by disrupting soil organic matter, thus
exposing formerly coated mineral surfaces. In the soil where dissolved Si d
id not change with drying, it had been demonstrated that Al-humus complexes
controlled Al solubility. We suggest that fissures in the organic material
caused by drying may have exposed formerly occluded binding sites that had
a higher Al saturation than had sites at the surface of humus particles.