The inherent fertility of tropical

The inherent fertility of tropical soils depends on their parent material, weathering
status, soil organic matter (SOM) content, and land use history. Two widespread
orders of weathered tropical soils are the Alfisols and Ultisols. Ultisols are
associated with regions subject to greater rainfall and weathering than Alfisols
and thus are more acidic and have lower concentrations of Ca, K, and Mg (Van
Wambeke, 1992). Both soil orders are dominated by low activity clays (kaolinite)
and generally have low concentrations of soil organic carbon and associated
nutrients (N, P and S). The warm climate and frequent, heavy rains in the humid
tropics accelerate the leaching and depletion of base cations from soils, including
Ca, Na, Mg and K. Silica is depleted at a faster rate than Al, resulting in a
enrichment of the parent material in Al (Ahn, 1993). Oxides of Fe and Al are
resistant to weathering and predominate, along with minerals like kaolinitic clay
and quartz sand. As the weathering process proceeds, soils become more enriched
in Fe and Al oxides, more acidic and therefore have a higher P fixation capacity.
Not all tropical soils are highly-weathered or have low fertility. For
example three classes of relatively fertile soils found in the tropics are Andosols,
Gleysols and Luvisols. Andosols are soils of volcanic origin, rich in cations and
fertile for agricultural production. However, tropical Andosols can also be rich in
colloidal weathering products such as allophane, imogolite, and ferrihydrite,
giving them a high P fixing capacity. Gleysols are formed under waterlogged
conditions and are commonly used for flooded rice production in the tropics.