Planet Earth Course (GEOL 110) BLT Form - Chapter 3 PDF

Summary

These lecture notes cover the Earth's shaping processes, focusing on climate change, weathering, erosion, and plate tectonics. The document explains factors influencing Earth's surface features and includes examples from different climates and regions.

Full Transcript

Planet Earth Course (GEOL 110)-
BLT form
Chapter 3: Earth Shaping processes
Delivery method: mainly online

Dr. Dalal Alshamsi
Geology Department, College of Science
United Arab Emirates University
Session 1
Earth surface shaping factors are:
1. Climate:
a) Weathering
b) Erosion
2. Plate Tectonics
Climate
Unlike the weather which changes over
short time, the climate is the average
weather conditions over a long period of
time.
Climate has changed throughout
geological time (millions of years).
What is climate change, and how do
geologists know about it?
The Earth’s temperature change naturally
over time scales ranging from decades, to
hundreds of thousands, to millions of years.
Proof of climate change is preserved in an
extensive range of geological settings,
including marine and lake sediments, ice
sheets and fossils (Geological Society of
London, 2010).
https://www.britishecologicalsociety.org/climate-change-emmisions-reduction-targets-scotland-bill-call-evidence/
 Climate
What are the driving forces of climate
change?
Many factors interact on different time scales and
cause the climate change:
Over millions of years the continents move,
oceans open and close, mountains rise and fall,
volcanoes erupt and emit gases. All of these
changes affect the atmosphere and oceans and
in turn the overall climate on earth.
Scientists think that climate change is driven by
changes in the Earth’s orbit axial tilting which
result in releasing CO2 from oceans.
Effects of climate change on earth shape
During ice ages, the sea
level drops. For example
in the most recent ice
age 12000 years ago,
the Arabian Gulf was
dry with only a river
channel.
In contrast, the ice
sheets melt and the sea
level rises in the green
house ages.
The earth in the most recent ice age 12000 years ago
Weathering
Weathering in general refers to a group of processes that are grouped into:
A. Mechanical weathering: rock disintegrates (breaks out) into
smaller particles without changing their chemical and
mineralogical composition.
B. Chemical weathering: rock dissolves into water and this
process will change the chemical and mineralogical
composition of the rock.

The weathering processes often are slow (hundred to thousands of years).
Mechanical weathering examples:
Frost wedging
Water penetrates cracks, then freezes.
The expanding ice wedges the crack apart
Thermal cracking
Hot conditions followed quickly by cold
conditions produce thermal stresses that
can crack the rocks
Root wedging
Plant roots invade a crack in the rock.
As the plant grows the root gradually
opens the crack in the rock.

Root wedging
Mechanical weathering

Boulder split by thermal stresses Tree roots wedging apart a rock
along a crack
Mechanical weathering in Jais Mountain, RAK
 Chemical weathering examples:
Oxidation
Fe2+ in minerals oxidizes to form Fe oxides like hematite (Fe2O3)

Dissolution
Carbonate minerals (like calcite which occurs
mainly in limestone) dissolve in slightly acid rainwater
Chemical weathering- dissolution in Hafit
Mountain resulted in cavities
 Erosion
Erosion is the removal
(transportation) of
weathered and
unweather materials
from their original place
to a lower elevation
drainage systems.

Erosion in Hafit Mountain produced by running water or wind
Weathering and erosion shaping effect differs
according to climate

Jebel Hafit Mountain was shaped in
Hot arid climate

Alps Mountains were shaped in
cold glacial climate
Session 2
Plate tectonics
The rocky outer skin of the Earth is a thin shell called the crust.
We live on the crust so we know more about it than the rest of the
Earth.
The crust is very thin and consists of two types of material:

1- Continental crust 2- Oceanic crust
Usually 10 – 70 km thick and relatively Only 3– 15km thick and denser
low in density. It has an average than continental crust. It has
composition like granite an average basalt composition
The crust is divided into a mosaic of “plates” that are variable in
size and are usually composed of both oceanic and continental
crust.

North American plate
has continental crust
and oceanic crust Each plate is outlined
by plate boundaries

Pacific plate is entirely
oceanic crust
Tectonics
The cause of plate movement is probably due
to the effect of giant thermally driven
The plates are not static – they are convection cells in the mantle. These transfer
moving, each in its own direction. heat from the core towards the surface.
The plates are moving in different directions:

1. Plates moving away from each
other = Divergent plate
boundaries
2. Plates moving toward from
each other = Convergent plate
boundaries
3. Plates moving parallel to each
other = Transform plate
boundaries
 1- Divergent plates
Divergent (splitting) starts in a weak part of As we learnt in chapter 1, basalt is the
crust, where the lava can rise up in a line. dominant rock type in the oceanic
This separation line is called Spreading crust! So the formed basalts around
ridge. the spreading ridge will be new
oceanic crust which means a new sea
will form in the area of divergent plate
Along the spreading ridge, a line of small boundaries.
volcanoes are erupting lavas.
The new sea opens more and more
When these lava cool and solidify, igneous with time forming am ocean.
rocks -particularly basalt- are formed. Most of the Earth’s seas and oceans
were formed due to the divergent
plate boundaries movement.

Examples: African Rift Valley, Red sea,
Atlantic Ocean.
 1- Divergent plates

Modified after: https://www.zmescience.com/science/what-is-wilson-cycle/
Divergent plates are
considered constructive
because a new oceanic crust
is created
1- Divergent plates
Most of the volcanism along the spreading ridges is under the sea.
In some cases the ridge reaches the surface of the ocean and the
volcanism can produce islands. For example: Iceland
2- Convergent plates
When two plates move toward each other, they meet. These
meetings (collision) will result in different phenomenon depending on
the crust type in each side!

Convergent plates might occur as:
1. Continental crust colliding continental crust
2. Continental crust colliding oceanic crust
3. Oceanic crust colliding oceanic crust
2- Convergent plates
1. Continental crust colliding continental crust

Results in:
1. Mountains building
2. Crust thickening = constructive
effect

3. Earthquakes
Example:
When Indian plate collide the
Eurasian plate, the Himalaya
Mountains were built up! www.Wikipedia.org
 About 225 million years ago,
India was a large island near the
Australian coast!
When Pangaea broke apart
about 200 million years ago,
India began to move northward,
until it collided Asia around 50
million years ago!
The result of collision was the
Himalaya Mountains!
https://pubs.usgs.gov/gip/dynamic/himalaya.html
The Himalayan Mountains marks the
line of collision
https://www.tes.com/lessons/OFrLtMf3T56kPQ/science-changing-earth
 2- Convergent Plates
2. Continental crust colliding oceanic crust
Results in:
1. The denser oceanic crust is subducted (going beneath)
under the continental crust
2. Destroying part of the oceanic crust, which is dipped
partially in the mantle and melt= destructive effect
3. The melted part will rise up as volcanic arc on the continent
4. Forming Trench at the area of subduction.
5. Earthquakes and may be Tsunami
* Trench is: deep zone and lies along the line where the two
plates meet.
* Subduction is zone where two plates meet.
Example:
The pacific plate collide the South American plate forming the
Andes Mountains (Andes volcanic arc).
Continental crust colliding oceanic crust

https://www.tes.com/lessons/OFrLtMf3T56kPQ/science-changing-earth
2- Convergent Plates
3. Oceanic crust colliding oceanic crust
Results in:
1. Both oceanic crust are dense, but the
older denser one is subducted under
the another.
2. Destroying part of the oceanic crust,
which is dipped partially in the mantle
and melt = destructive effect
3. The melted part will rise up as large
areas of lava. These lavas cool and
solidify forming volcanic islands in the
sea (like Japan Islands, Mariana
Islands).
4. Forming Trench at the area of
subduction.
5. Earthquakes and may be Tsunami
Oceanic crust colliding oceanic crust Mariana Islands Mariana Trench

https://slideplayer.com/slide/5913252/ www.geology.com
 3. Transform Plates
The plates simply slide past each
other, with no divergence and no
convergence
The friction from this movement
might result in earth quakes
This type of boundary is conservative,
because neither crust is destroyed nor
is created.
Examples:
1. Dibba fault zone in the UAE
2. San Andreas fault in California, USA
https://www.researchgate.net/figure/Epicenter-map-PDE-data-for-the-UAE-and-southern-Iran-
Solid-stars-mark-epicenters-of_fig1_226345564
End of Chapter 3