Weathering and Soil

Weathering and Soil

Weathering

- Natural earth processes that occur on the surface that work to break down rock are called weathering

Effects of Weathering
Weathering breaks rock down into smaller and smaller pieces called “sediments”.
Sediments are classified into different sized particles: sand silt clay
Sediments gradually change into soil over time
The formation of soil depends on the amount of weathering that occurs in a given location.
Weathering has changed the surface of the earth over millions of years.
Mountains have worn away into hills and then flat plains because of weathering.
2 Types of Weathering
Mechanical Weathering
When rocks are broken apart by [physical processes.
Chemical make-up of the rock stays the same.
Physical properties of the sediments are the same as the rock from which the sediments eroded.
Causes
Growing of plants on rock—Roots grow in small cracks in rocks and force the cracks further apart.
Burrowing of animals and insects—As animals dig their dens or tunnels through soil they loosen sediments and push them to the surface where erosion from wind and water can act on them
Ice Wedging—Water seeps into cracks in rock and then expands when it freezes. The pressure from the expanded ice forces the cracks to widen. When the ice thaws, more water can seep into the wider crack and the process repeats itself.
Effects- Mechanical weathering forces rock to break into smaller and smaller pieces allowing more rock to be exposed to more and more erosion and weathering. The cycle will continue forever.
Chemical Weathering
When chemical reactions dissolve the minerals in rocks or change them into different minerals.
This changes the chemical composition of the rock and makes it weaker.
Natural Acids
Carbonic Acid is formed when CO2 in the air mix with H2O
Reacts with minerals such as calcite which is a major component of Limestone rock.
Natural Acids react with granite and sandstone to form kaolinite clay over thousands of years.
Plant Acids
Roots of decaying plants give weaken rock by giving off acids that dissolve minerals in the rock.
Oxygen
Oxidation occurs as O2 reacts with metallic minerals such as iron in rock.
Hematite transforms into a rust like material called limonite
Effects of Climate
Mechanical and Chemical weathering occur everywhere on the planet all the time.
The climate affects the amount of weathering that occurs
Climate- the pattern of weather that occurs in a particular area over many years.
Chemical weathering occurs at a faster rate in warm wet climates. Tropical regions see a lot of chemical weathering.
Physical weathering occurs at a faster rate in cold, windy climates.
The climate of a region also affects the rate that a type of rock will weather.
Marble will weather more quickly in a warm wet climate than it would in a dryer climate.

The Nature of Soil

What is soil? Soil is a mixture of weathered rock, decayed organic matter, mineral fragments, water and air.

Formation of Soil
Takes thousands of years to form and ranges from very thick in some places where the weathering process has been active for years and years to very thin where weathering has just begun to take place.
Lots of factors affect the formation of soil such as: climate, slope, types of rock, vegetation, and the length of time that rock has been weathering.
Different kinds of soil develop in tropical regions than polar regions.
Composition of Soil
Soil is a mixture of weathered rock, decayed organic matter, mineral fragments, water and air.
Weathered rock-Form sediments of sand, silt and clay that makes up part of soil.
Decayed organic matter from plants and animals turns into a rich, dark colored material that becomes a source of nutrients plants called humus.
Worms, insects borrow in the soil and serve to mix the humus into the soil.
Air / Water - Seeps into the spaces in between the sediments, keeping the soil aerated and moist.

Soil Profiles
Horizons- Layers of soil with varying degrees of plant and animal life and mineral composition.
A Horizon -Top layer of soil
Covered in “litter” (twigs, leaves and other organic material) that will be converted into humus over time.
Litter prevents erosion and keeps erosion down
Dark and rich with lots of nutrients for plants to grow.
B Horizon- Below the A layer
Lighter in color due to lack of litter and organic matter.
Contains less humus and smaller sediments such as silt and clay
Contains material that has leached from the A Horizon
Leaching is the removal of minerals that have been dissolved in water. Water seeps down through the A layer, bringing only some of the dissolved minerals to the B layer.
C Horizon- Below B layer.
Even lighter in color than the B layer—indicating even less nutrients
Bottom of the soil profile
Contains coarse sediments and large rocks toward the bottom—gravel and “bedrock” which is called “parent material”
***** Glaciers deposited soil all across the USA thousands and thousands of years ago. If we dug down through the soil profiles and got to bedrock, that rock is NOT the parent material of the soil in the layers above it. Glaciers moved that soil from it’s parent material long ago.
Soil Types
Vary from place to place and are affected by
Climate
Deserts- soil lacks organic material because not too many things can live or grow in deserts. Horizons are thinner than in other climates
Prairie soils have thick, dark A horizons due to amount of vegetation and animal life that exist in that climate
Temperate forest soils – Thinner A and B horizons that have rich mineral content due to leaching from abundant rain fall.
Tundra and tropical areas have distinct soils because of the rainfall, vegetation and animal life that each environment can sustain
Other Factors
Parent Material has an effect on the type of soil that comes from it
Clay- comes from basalt
Time affects soil development. Soil will be thicker and richer if weathering has occurred over a long period and vice versa.
Slope- There will be more run off if the grade of the landscape sloped, allowing less soil to build up in thick layers toward the top of the slope.

The bottom of the slope (bottomlands) tend to build up thicker layers of soil that are rich and dark.

Soil Erosion
Soil as a Resource
Farming / Agriculture is necessary. We need to find ways to keep the top soil (A horizon) in place because this is where the humus is and where the soil is the most nutrient rich for plants.

Causes and Effects of Soil Erosion
Agricultural Cultivation—increasing global populations leads to increased farming. Plouging churns up the soil, enabling topsoil to be eroded by wind and rain. Over time, the quality of the soil also worsens.
Forest Harvesting—as forests are cleared or cut back soil is exposed and erosion increases. Soil quality degrades.
Overgrazing—when ground vegetation is grazed severely, vegetation cannot come back quickly enough. If roots are exposed to sun and wind they will dry up before they can recover. New plant material will not grow and consequently less organic material in the soil. Soil quality degrades and top soil erodes away.
Urban construction—Vegetation is cleared for roads, neighborhoods, shopping centers. Top soil is exposed to weathering and then erodes away.

Preventing Soil Erosion
Manage Crops
Planting “shelter belts” of trees as a barrier to wind that might erode soil away
Plough in different directions to cut down on water erosion
Properly manage grazing of livestock
No-till farming—dead vegetation is left in fields to add nutrients to soil and hold soil in place
Reduce Erosion on Slopes
Contour farming- Using natural contours of the land reduces erosion because it slows the flow of water down the slope
Terracing- flat areas are cut into slopes so that plants can grow and soil layers can thicken.
Reduce Erosion at Construction Sites
Cover exposed soil with stray, mats, tarps and mulch to decrease erosion.
Topsoil added after construction project is over and then is replanted with grass and other vegetation to keep the soil from eroding.
Retaining walls along slopes keeps soil and rocks from sliding down hills.