Mechanical and Chemical Weathering

Since igneous rocks form at high temperatures, and under pressure conditions ranging from one to several atmospheres.  However, the conditions at the Earth's surface are somewhat different than the conditions at which most rocks and minerals form.  Therefore, the materials are no longer at equilibrium when they are exposed to surface conditions.  Under these conditions, there is a tendency for all ordered systems to seek lower levels of energy or order.  This is all done through weathering.

Weathering - the disintegration and decomposition of rock at or near the surface of the earth.  It affects the rocks in place and no transport is involved.  This distinguishes weathering from erosion.

Mechanical/physical weathering - physical disintegration of a rock into smaller fragments, each with the same properties as the original.  Occurs mainly by temperature and pressure changes.

Chemical weathering - process by which the internal structure of a mineral is altered by the addition or removal of elements.  Change in phase (mineral type) and composition are due to the action of chemical agents.  Chemical weathering is dependent on available surface for reaction temperature and presence of chemically active fluids.  Smaller particle sizes weather by chemical means more rapidly than large particles due to an increase of surface area.  Look at the diagram below and you will see that as the particles get smaller, the total surface area available for chemical weathering increases.

Erosion - the incorporation and transportation of weathering products by a mobile agent such as wind, water, ice.

All three processes may act independently, but will more often than not, occur simultaneously.  Different circumstance will have one weathering process more important than another.  The processes may also act in concert with one another.

Types of Mechanical Weathering:
Frost Wedging - water expands when it freezes.  This photograph shows the individual layers within the sedimentary rock breaking apart through repeated cycles of freeze-thaw.  A similar process happens when the rock is repeatedly wetted and dried as salt crystals dissolve from the rock then grow when it is dried.  Both processes can result in the rocks being heaved - so what was once a nice regular pattern of bricks set in a pavement will eventually become a chaotic jumble of bricks oriented every which way.  Thermal Expansion and Contraction - heating causes rock to expand, cooling results in contraction; different minerals expand and contract at different rates.  This phenomena will look very similar to frost wedging and salt crystal growth, but will typically happen in climates that undergo extreme diurnal temperature changes.
Mechanical Exfoliation - rock breaks apart in layers that are parallel to the earth's surface; as rock is uncovered, it expands (due to the lower confining pressure) resulting in exfoliation.  The photograph is from G. K. Gilbert (1903) in Sequoia National Park.  The granite boulder is shaped by exfoliation; the boulder is about 40 feet in diameter, and the separated fragment resting on it is about 10 feet thick.  Exfoliation is very common whenever plutonic igneous rocks are exposed.  Since the plutonic rocks cool at depth under great pressure, they essentially de-pressurizes once the overburden is removed.  This causes sheets of rock to peel off subparallel to the earth's surface, or whatever is the least pressurized surface.
In this photo from Yosemite National Park, the exfoliation sheets are subparallel to the valley walls.
Abrasion - physical grinding of rock fragments.  Here, the photo shows some pits that have been eroded into the rock by sandblasting.  Along with the physical weathering (the sandblasting), chemical weathering has taken place as the rock shows some signs of solution weathering as well.
Another photograph which shows the powerful effect of wind generated abrasion is the Double Arch from Arches National Park.  The edges of the arches have weathered along joints, preexisting tectonically controlled vertical surfaces in the rock.  Then mechanical abrasion took over and carved out the arches.

Types of Chemical Weathering:
Dissolution

H2O + CO2 + CaCO3  --> Ca+2 + 2HCO3-
water + carbon dioxide + calcite dissolve into calcium ion and bicarbonate ion
Dissolution is very common in areas that have a great deal of limestone.  Acidic waters (from pollution or natural) dissolve limestone allowing for additional water to gain entrance.  Can cause sinkholes and karst features as well as dissolution of statutes and grave stones.

Oxidation (rust)

4Fe+2 +3O2 --> 2Fe2O3
ferrous iron + oxygen combine to form ferric iron oxide (hematite)

Will happen to all iron-bearing silicates to varying degrees.  Common reaction minerals are hematite, limonite, and goethite.

Hydrolysis
2KAlSi3O8 + 3H20 --> Al2Si2O5(OH)4 + 4SiO2 + 2K(OH)
potassium feldspar in acidic water hydrolyses to kaolinite + quartz + potassium hydroxide

Silicate minerals (unstable at the earth's surface) weather to form clay minerals such as kaolinite (stable at the earth's surface).  Feldspars typically weather to produce clay minerals.


Factors that influence chemical weathering
Climate
Living Organisms
     bioturbation
     acid production and mineral decomposition
Time
Mineral composition
    Goldich Dissolution Series
     (Bowen's Reaction Series)

Chemical Weathering Products
    Clays
    Metals ores
    Rounding of boulders (chemical exfoliation)



 
 

Soils and Soil Formation

Dependence of weathering type on the mean temperature and annual rainfall.

Weathering rates depend on the composition of the rock, temperature range and rainfall amount.  Weathering produces soils.  Soils may or may not remain in place, and any soil may be a combination of residual and transported material.

Residual soil: Remains in place; has not been transported (gruss).

Transported soil: Transported by wind or water and deposited.
 

A complete soil profile will have the following components:

O horizon:  Organic debris and leaf litter on the surface.

A horizon: Topsoil - leaching, water movement down, Organic and Mineral material transported downward.

B horizon: Subsoil - accumulation of dissolved material and fine clays, hardpan.

C horizon: Partially altered parent rock material.

Bedrock:  Unweathered parent rock material.


These horizons are not present in all soil profiles. In areas of rapid erosion, B & C may be present or C only. In some areas no soil profile will develop at all.

Factors in Soil Formation

  1. Climate: The greater the rainfall amount, the more rapid the rate of erosion and leaching.  Laterites form in humid climates where only Al2O3 (Bauxite) and Fe(OH)3 remain.
  2. Topography: The steeper the surface slope, the more likely any eroded material is to be transported out of the system.
  3. Parent Material: Granites are more resistant to weathering than gabbros.  Sandstones are more resistant to weathering than limestones in humid climates, but limestones are more resistant than sandstones in arid climates.
  4. Plant and Animal activity: Plant and animal activity produces humic acids that are powerful erosion agents.  Plants can physically erode as well as chemically erode.  Plants stabilize soil profiles, Animals (including man) tend to destabilize the soil profile, increasing erosion.
  5. Time: Reaction rates are slow, the longer a rock unit has been exposed, the more likely it is to be weathered.
These factors can be remembered by the acronym ClORPT - Climate, Organic activity (plants and animals), Relief (topography), Parent material, and Time.
 

Mineral stability

Sediments are the by-product of weathering.  Sediments are particles of minerals, some of them altered from the original rock, some simply reduced in sized, and some new minerals by reaction.  The stability of minerals can be predicted using the Bowen's reaction series, however, in the case of the weathering series this is known as the Goldich Dissolution Series:

Olivine

        Mg Pyroxene                                             Calcic Plagioclase

                Mg-Ca Pyroxene                          Calcic-Alkalic Plagioclase

                        Amphibole               Alkalic-Calcic Plagioclase

                                Biotite  Alkalic Plagioclase

                                   Potassium Feldspar

                                   Muscovite

                                   Quartz
 

Minerals crystallize from a melt at different temperatures during the migration and emplacement of the magma.  Those minerals that crystallize at higher temperatures will be the least stable at the surface.  From this it is obvious that quartz will be the most stable mineral in the weathering environment, and will be a dominant constituent of sediments and sedimentary rocks.