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Mechanical Weathering
Includes all processes that crack, abrade, crunch, and otherwise break rocks.
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Unloading Exfoliation
Expansion of igneous rock at surface pressures causes fracturing and shedding of outer layers Fig
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Fig
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Mechanical Weathering
Frost/Ice Wedging Ice is less dense than water so water expands as it freezes.
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Mechanical Weathering
Frost/Ice Wedging
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Mechanical Weathering
Abrasion Wearing away of rock by grit suspended in water or air
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Mechanical Weathering
Abrasion
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Mechanical weathering is an inefficient way to break down rocks
Mechanical weathering is an inefficient way to break down rocks. It does, however, increase the surface area on which chemical weathering can act.
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Chemical Weathering Break down of rocks due to chemical reactions.
This is by far the most important of the three kinds of weathering.
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Chemical Weathering Acid/Base Reactions
Changes in acid or basic conditions cause break down, e.g. limestone dissolved in acid rainwater
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pH of natural and polluted rainwater
Chemical Weathering Acid/Base Reactions Box f2 pH of natural and polluted rainwater
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slate limestone Differential weathering of slate and limestone headstones. The limestone dissolves much more readily with acidic rainwater. Fig a
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Oxidation/Reduction Reactions
Chemical Weathering Oxidation/Reduction Reactions Loss or gain of an electron from an element (e.g., C, Fe or Mn). Oxidation usually results in the formation of an oxide, e.g., “rusting” of iron-bearing minerals by oxidation of iron.
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Oxidation/Reduction Reactions
Chemical Weathering Oxidation/Reduction Reactions FeS + O2- + H2O FeO.OH +S2-
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Hydration/Dehydration
Chemical Weathering Hydration/Dehydration Addition and subtraction of H2O into the mineral to form a different mineral, e.g., anhydrite (CaSO4) + H2O gypsum (CaSO4*2H2O) + H2O
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Chemical Weathering Hydrolysis
Reactions between H+ and OH- and silicate minerals yielding soluble positively charged ions and silica in solution. Hydrolysis is the main decay pathway for silicate minerals (remember, the most abundant minerals in the Earth’s crust are silicates!). Further reactions result in the formation of clay minerals.
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Chemical Weathering Hydrolysis Feldspar (microcline)
Feldspars chemically break down when exposed to surface conditions, and form clay minerals through the process of hydrolysis Feldspar (microcline) KAlSi3O8 + H+ + H2O H4SiO4 + KAl3SiO10(OH)2 Illite (clay mineral) Feldspar (albite) NaAlSi3O8 + H2CO3 + H2O Na + H4SiO4 + Al4Si4O10(OH)8 Kaolinite (clay mineral) Other common clay minerals: schmectite, gibbsite, montmorillonite, etc.
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Fig
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Bowen’s Reaction Series and Weathering
felsic Felsic minerals are most resistant to chemical weathering. Mafic minerals are least resistant to chemical weathering.
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Biological Weathering
Weathering due to the activities of living things (plants, animals, fungi, bacteria, protists, etc.) All organisms alter their local environments, causing both physical and chemical weathering. Plants are the most obvious destroyers of rocks, but bacteria are by far the most important biological weather-ers.
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Biological Weathering
Lichen breaking down rock. Primarily (bio)chemical
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Biological Weathering
Root Wedging Tree roots breaking down rock. Both physical and chemical weathering
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Weathering Mechanical Weathering Chemical Weathering
Biological Weathering
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P Quartz Feldspar Mica Physical Weathering resistant Hardness = 7
no cleavage, brittle Tenacity - strong susceptible resistant Feldspar Hardness = 6 2 directions of cleavage, brittle Tenacity - intermediate susceptible resistant Mica Hardness = 2.5 1 perfect cleavage, elastic Tenacity - weak susceptible
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P C Quartz Feldspar Mica Chemical Weathering resistant
Chemically resistant to most surface processes susceptible resistant Feldspar Breaks down quickly to form clay minerals susceptible resistant Mica Breaks down slowly to form clay minerals susceptible
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Quartz: physically breaks down to form smaller quartz grains
Weathering Quartz: physically breaks down to form smaller quartz grains physical break down fracture Feldspar: physically breaks down to form smaller feldspar grains, chemically breaks down to form clay minerals physical break down cleavage chemical break down hydrolysis Mica: physically breaks down to form smaller mica grains, chemically breaks down to form clay minerals physical break down cleavage chemical break down hydrolysis
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Sediment Produced from Granite
Given enough time, all that will remain will be sand-sized quartz grains and mud-sized clay minerals
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Clast Sorting The farther the clasts have traveled from the source, the more well sorted they tend to be.
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Clast Size Comparisons
gravel coarse sand fine sand Large clasts require more energy to transport than small clasts. Smaller clasts tend to be transported greater distances than larger clasts. silt and clay
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Clast Rounding As clasts are rolled around during transportation, sharp corners tend to be knocked off, and the clasts become more rounded the farther they are transported. Angular grains are usually found only near the source rock.
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