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Factors affecting weathering
Endogenetic (geological, factors are related to the rock characteristics)
rock strength/hardness
generally, weaker rocks get weathered more easily than stronger rocks --> granite vs sandstone
however, this does not hold true all the time as even the hardest/strongest rocks can be betrayed by the presence of joints and lines of weaknesses which make them as/more vulnerable to weathering agents --> granite: vertical and horizontal joints, pseudo bedding planes and sheet joints
mineral and chemical composition
determines the degree of susceptibility to weathering
determines the specific type of chemical weathering that are/is likely to operate on the rock
e.g. calcium carbonate in limestone and chalk --> carbonation-solution
feldspar in granite --> hydrolysis
iron compounds --> oxidation
colour
affects insolation weathering in terms of the differential rates of expansion and contraction
usually more stable minerals are light-coloured while less stable ones are dark-coloured --> darker-coloured rocks are more prone to chemical attacks than lighter-coloured ones in general
heterogenous vs homogenous rocks
rock texture
coarse-grained vs fine-grained
coarse grained --> individual minerals can undergo selective chemical attack
fine grained --> crystals are more tightly bonded thus increasing their strength and coherence BUT crystal boundaries provide potential lines of weaknesses that may be exploited by weathering
usually fine-grained rocks weather more quickly than coarse-grained ones
rock structure
refers to the presence of joints and cavities
Provide agents of chemical and physical weathering access into rock masses
Exposes the subsurface portions of rock to agents of weathering --> allowing weathering to take place not just on the surface/near the surface, but deep underground as well as in the Deep Weathering Exhumation Theory
may be inherent or may develop as time passes and rock is subjected to different types of stresses associated with different tectonic processes
massive vs densely jointed rocks
Types of lines of weaknesses
Bedding planes --> horizontal joints or junctions separating different layers of sedimentary rock (limestone, sandstone, chalk etc.); provide routes for the movement of acidulated water --> formation of limestone caves and caverns as the water table migrates over time
Lines of cleavage --> common in metamorphic rocks
Master joints --> very extensive and usually larger than normal joints
formed as intrusive igneous rocks cool and contract
their intersection with bedding planes and other joints give weathered/broken up rocks different shapes and patterns e.g. granite and gneiss usually have cuboidal jointing pattern --> block disintegration
DENSITY of joints --> has the ability to affect the form and shape of landforms
dense jointing pattern --> agents of weathering have greater access to the rock --> more intense weathering
Exogenetic (factors other than rock characteristics; pertaining to the external environment)
Climate
Water (precipitation)
Needed for virtually every weathering process
Acids
Solution
Chemical weathering is most effective with the presence of abundant groundwater that is constantly renewed (to prevent neutralisation)
In climates where water is scarce (savanna, semi and hot deserts) physical weathering is more dominant
Temperature
influences the rate of weathering --> Van Hoff’s rule
weathering in tropical areas usually 4 times faster
temperature range is also important, particularly for physical weathering
large/wide temperature range --> insolation weathering/thermal expansion in desert regions
temperature that hover around freezing point of water --> frost action in periglacial regions
Vegetation (affected by and closely related to climate)
decaying vegetal matter produces organic acids for biochemical weathering
tropical rainforest vs coniferous forests
tropical rainforest supply 100-200 tonnes of litter per hectare per year
coniferous forests supply 20-25 tonnes of litter per hectare per year
Due to the stark difference in the amount of litter produced between tropical and coniferous forests, rates of weathering can differ with those in tropical rainforests being 40 times faster then those in coniferous forests
Relief/topography
High relief/altitude --> lower temperatures--> frost action
steep slopes help transport weathered material away (mass movement), continually exposing new rock to weathering agents
Steep slopes promote drainage (overland flow, throughflow), inhibits infiltration into the ground and therefore hampers/limits deep chemical weathering
Gentle slopes hampers the removal of regolith and moisture but promotes/enhances deep chemical weathering as water is more likely to infiltrate and not removed so quickly
ASPECT (direction at which the slope is facing)
affects insolation receipts and hence temperature and evaporation rates --> responsible for the local variations in weathering rates
Northern hemisphere: south-facing slopes receives more sunlight and hence have higher temperatures --> more melting and freeze-thaw cycles --> more physical weathering
In cold but not frosty areas in the northern hemisphere: south-facing slopes receive more sunshine and have more vegetation --> biological and chemical weathering
Time
rocks develop more lines of weaknesses over time --> increases their susceptibility to weathering
climate change --> vegetation types may also change over time
however, the weathered products do not change with time --> at present times, we can still see evidence of previous climates through the remaining weathered products
time also affects relief via tectonic uplift or erosion
Human activity
air pollution --> more acidic rainwater
agriculture, quarrying, mining --> removal of overlying rocks, protective vegetation, exposing underlying rocks to agents of weathering