One of the most important scientific discoveries was how soil forms spontaneously from rock. Under the influence of physical factors like deformation by heat and cold, assault by wind, rain, hail and ice, and the enormous levering forces of water expanding into ice, solid rock is shattered into smaller pieces (see picture). But however small these fragments, they still have the same properties as the parent rock.
Being formed under high pressure and temperatures, the crystals of the minerals in the rock are somewhat unstable at surface pressure and temperature. Particularly when attacked by acids that etch away the soluble components in the minerals, the crystals fall apart, albeit very slowly. It is called spontaneous weathering, but it is accelerated considerably under the influence of vegetation and its acids (chemical weathering).
During the weathering process, four components are released:
- minerals in solution (cations and anions), the basis of plant nutrition.
- oxides of iron and alumina (sesquioxides Al2O3, Fe2O3).
- various forms of silica (silicon-oxide compounds).
- stable wastes as very fine silt (mostly
fine quartz) and coarser quartz (sand). These have no nutritious value
for plants.
- parent material
- time
- climate
- atmospheric composition
- topography
- organisms
Depending on temperature and rainfall, new
minerals are formed. The oxides of iron and alumina combine with silica to
form clay. In temperate regions a three-layer clay is formed, which is
weak, swells under moisture, and clogs. It is able to absorb large amounts
of water but is rather heavy on plant roots, blocking the oxygen the soil
organisms need. Because clay has a charged surface area, it is able to
bind and retain minerals and nutrients (Cation Exchange Capacity). The
valuable nutrition for plants won't leach away easily in three-layer
clays.
Two-layer clays are formed in hot, humid tropical regions, producing
arable but easily dried soils. These clays are not able to hold much
water, or nutrients, but are still very much better than sand.
Soil's
productivity is mainly due to the clays in the soils. Knowing that clay
particles are very small (less than 2 microns), one can imagine that this
component is easily eroded out of the soil. Its small size prevents it
from sedimenting out rapidly in water, resulting in rivers, lakes and
ocean water staying turbid for a long time after rains have ended.
The mix of sand, silt and clay is called a loam. In this diagram, the
triangle represents all possible combinations of the three. Soil
specialists use names for the various loams, as indicated in the diagram.
A loam can be dried and pounded in the laboratory and passed through
sieves to separate the mix by particle size. From the diagram, the
official composition of 'loam' can be inferred - sand:silt:clay =
40:40:20. (Draw lines parallel to each side and read the left-hand
values.)
Sand is very workable but won't hold water, or nutrients well. Loam is poor in nutrients, reasonably workable, but holds water well. Clay is difficult to work, compacts easily, but holds water and nutrients well, but is reluctant to release these to plants. As the diagram shows, the various loams derived from the three base components, have varying workability, water holding capacity and cation exchange capacity (CEC).
Not only temperature and moisture affect soil formation but also the level of the groundwater table and the steepness and elevation. As can be seen, soil formation depends on many factors, regional and local, resulting in an almost infinite number of different soils, each having different needs. Nutrients therefore, can vary considerably from patch to patch, requiring careful application and observation.
Information provided by: http://www.seafriends.org.nz