Plate Tectonics Review via Google Earth
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Dec 6, 2023
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Plate Tectonics Review via Google Earth
Due October 2
Plate tectonics is a unifying framework for understanding the dynamic geology of the Earth. The theory posits that the outermost layers of the Earth (the crust and uppermost mantle) make up the brittle lithosphere
of the Earth. The lithosphere is broken up into a number of thin plates
, which move on top of the asthenosphere
(middle mantle). The asthenosphere is solid, but flows plastically over geologic time scales. Plate interiors are relatively stable, and most of the tectonic action (earthquakes, volcanism) takes place where plates meet – where they collide at convergent boundaries
, move away from one another at divergent boundaries
, or slide past one another at transform boundaries.
Reconstructions of the Earth’s tectonic plate locations through time are available, for example, at:
http://www.ig.utexas.edu/research/projects/plates/recons.htm#movies
http://www.scotese.com/newpage13.htm
http://www.ucmp.berkeley.edu/geology/tectonics.html
But how do we define plates and plate boundaries? On what are plate reconstructions and animations based? How do we know plates are moving, how can we track their positions in the past, and how can we predict their positions in the future? To answer these questions, this assignment guides you through an examination of patterns on Earth – the topography of the earth’s surface above sea level, the bathymetry of the ocean floor below sea level, and the distribution of earthquakes and volcanic rock ages. You’ll then use geologic data to determine long-term average plate motions. To do this, you’ll use the program Google Earth, and Google Earth layers compiled from various sources. A. Getting started with Google Earth
On your computer, install the latest version of Google Earth
from
http://earth.google.com/
Once installed, open Google Earth, under the Tools/Options/3D View/ menu choose the “
Decimal Degrees
” and Meters Kilometers
” options and makes sure the “
Show Terrain
” box is checked.
Open the View menu. Go ahead and experiment with the options, but in general you should
just have the Tool Bar
, Side Bar
and Status Bar
checked. Also on the View menu, hover over Navigation and you will see several options for the compass arrow and slide bars in the
upper right corner of the Google Earth screen. “
Automatically
” is a good choice as it leaves a ghost of the image visible until you hover over it.
Load the DynamicEarth.kmz
file (found on our D2L page under Content/Plate Tectonics) into GE. You should be able to double-click on the filename and it will open within GE. Or, you can download the file onto your computer, and open it in GE by using File/Open and navigating to the file.
Once the DynamicEarth.kmz is loaded, click and drag to move it from “Temporary Places” to
“My Places.” Then save “My Places” by clicking File/Save/Save My Places.
DynamicEarth.kmz will now be available every time you open GE on this particular computer. When you exit, GE should save “My Places” for the next time.
But you should manually save “My Places” whenever you make significant changes to it, as Google Earth does not autosave during a session.
Ok, with an active Internet connection, you now have an interactive view of the earth! Take some time to explore the Earth with Google Earth and figure out how the navigation works using the keyboard, your touch pad, your mouse. For example:
Zoom in and out, move N, S, E, W, grab and spin the globe, etc. The resolution will change as you zoom. Clicking on the “N” of the navigation compass reorients the view so north is “up.”
At top left, “search” (and fly to) any place of interest. Zoom in and click on the “street view” icon (orange stick figure under the compass at top right) to explore an area as if you were on foot
Zoom in to see individual buildings, roads, cars, etc. (Find MTSU or your house/apartment.)
Go 3D - zoom into a significant topographic feature (e.g. Mount Everest, the Grand Canyon, Niagara Falls). Hold the Shift key down and tilt the terrain using the Up/Down arrows to tilt the terrain, and spin the terrain using the Right/Left buttons. Do the same thing for topographic features on the ocean floor. Note that under Tools/Options/3D View you can increase the vertical exaggeration by up to 3x. This is
useful to emphasize subtle features, but is pretty scary when you look at the Grand Canyon that way!
On the Google Earth tool bar, click the clock-with-an-arrow icon to explore historical imagery in an area of interest (views through time of the Princeton campus, for example)
By clicking and dragging, you can move things that you have found and want to save, from the “Search” menu into “My Places.” You can also re-organize “My Places” by adding and deleting items, changing the order of things, making subfolders, etc.
Explore the built-in items under the Layers menu at bottom left, and Dynamic Earth layers in your Places menu. Expand and contract the folders and subfolders, turn various items on and off, etc. For example, with the Dynamic Earth/
Volcanoes of the World layer displayed, right-clicking on a volcano brings up an information box about it. 1.
Find something interesting, significant, cool, etc. to share on Google Earth with your classmates in our class session. This can even be something that other people have developed – if you want to spend some time poking around on the web to see what others have found. Feel free to include more than one.
Give a brief description of your item(s) below:
-
TexasGulf Potash Ponds
-
38°29’0.16″N 109°40’52.80″W
-
These are Potash harvesting ponds near Moab
-
The ponds are dyed blue to increase evaporation to harvest
the potash.
B. Topographic Patterns Uncheck all of the layers, except the plate boundaries, and focus on topographic features of the earth.
Topography of the earth ABOVE
sea level
2.
Are mountains randomly distributed on the continents, or do they tend to occur in particular patterns (clusters, linear chains, arcs, etc.)?
-
Mountain ranges occur in particular distribution patterns that correlate with plate tectonics. They indicate where continents underwent collision and orogeny, and eventually rifted apart.
3.
Find Mt. Everest, the highest point on earth. Zoom in enough to see the summit, then pan your cursor around to locate the highest point (elevations shows up in the status bar at the bottom, as long as View/Status Bar is selected): 8756 meters
Topography of the earth BELOW sea level
We are all relatively familiar with the topography of the Earth’s surface above sea level, but less
so with the bathymetry of the Earth below sea level. Before this was known, most people assumed that the seafloor was relatively flat and featureless, and personal experience with lakes and rivers suggested that the deepest part would be in the middle. Actual mapping of the
sea floor, however, showed some surprises. Such mapping began in the 1930’s but accelerated during World War II with the advent of submarine warfare. Princeton Geosciences Professor Harry Hess played a pivotal role; as captain of the USS Cape Johnson he used the ship’s echo-sounder to “ping” the seafloor and measure depth as the ship traversed the Pacific Ocean between battles. After the war, this data led him to propose seafloor spreading, a process crucial to the development of the theory of plate tectonics.
Modern methods to measure bathymetry include multi-beam echo sounders that map a wide swath of seafloor, and satellite measurement of variations in sea level due to variations in gravitational pull over bathymetric features – sea level is slightly lower over low spots on the sea floor and slightly higher over high spots.
4.
Using Google Earth, “fly to” Challenger Deep, the deepest place on Earth (once Google Earth gets you there, you may have to zoom out to see where you are). Where is it?
-
Challenger deep is located in Mariana Trench in the Philippine Sea off the coast of Guam. 5.
Challenger Deep reaches 11 km (36,000 ft) below sea level. Which is greater, the elevation
of Mt Everest (see question 3) above sea level, or the depth of Challenger Deep below sea level, and by how much?
-
On Google Earth, Challenger Deep is approximately 10382 meters below sea level. This depth below sea level is greater than Mt. Everest’s elevation by 1626 meters.
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6.
Give the names and locations of three other ocean trenches on earth.
-
Tonga Trench - southwest Pacific Ocean off the Coast of Australia, near the island of Tonga.
Contains the Horizon Deep, second deepest to the Challenger deep. -
Philippine Trench – Located 56 miles off the coast of the Philippines and contain the third deepest point in the world, the Galathea Depth.
-
Kuril- Kamchatka Trench – located in the North Pacific Ocean, near the Kuril Islands and off the coast of Kamchatka.
C. Seismic Patterns
An earthquake is a vibration of Earth caused by the sudden release of energy, usually as an abrupt
breaking of rock along planar fractures called faults
. Earthquakes originate at a point called the focus
(or hypocenter
) which is not at the surface of the earth, but instead at some depth within the earth. The epicenter
of an earthquake is the point directly above the focus on either the land surface or seafloor; the depth of an earthquake has nothing to do with water depth, but instead is the depth in the solid earth from epicenter to focus. Only rocks that are cold and brittle (the earth’s lithosphere
) can be broken in earthquakes. Rocks that are hot and ductile will stretch and deform slowly over time without breaking (the earth’s asthenosphere
) – and thus do not produce earthquakes. So observing where earthquakes occur, both horizontally and with depth, tells us something about where stress is concentrated, and also about the material properties of the earth. Expand the Seismicity item in the Places menu and click “on” the “Twenty years of large earthquakes” layer to show the epicenters of large earthquakes (those with magnitudes >= 6.0) during a 20-year period.
7.
Describe any patterns you see in the distribution of earthquake epicenters over the Earth’s surface - do they form lines, arcs, circles or clusters? Are patterns connected or disconnected?
-
Earth quake epicenters are correlated to their proximity
to plate boundaries. Many form in lines, arcs, and
clusters, but in context to outlines of plate boundaries,
their distribution follows such pattern. The majority of
linear patterns of earthquakes appear on Convergent
plate boundaries. Many of the earthquake clusters tend
to disconnect when there is another boundary type close
by. D. Volcano Patterns
A volcano
is an opening in the Earth’s surface through which melted rock (
magma
), volcanic ash and/or gases escape from the interior of the Earth. 8.
Leaving the seismicity layer on, click on the “Volcanoes of the World” layer. Describe the relationship between the locations of most active volcanoes and locations of earthquakes:
-
Active volcanoes and earthquakes are both related to plate motion. Locations with active volcanoes often experience not only more earthquakes, but ones of higher magnitudes since they most abundantly occur along convergent plate boundaries where subduction is occurring. E. Plate Boundaries
The theory of plate tectonics posits that the Earth’s lithosphere is broken into a finite number of jigsaw puzzle-like pieces, or plates
, which more relative to one another over a plastically-deforming
(but still solid) asthenosphere. The boundaries between plates are marked by active tectonic features such as earthquakes, volcanoes, and mountain ranges and there is (relatively) little tectonic activity in the middle of plates. Unclick all the layers, and then click on the “plate boundary model” layer (click the box to show it and then click the + or arrow to expand the legend). This shows plate boundaries and the names of major plates.
Find the boundary between the African and South American plates
9.
Where is this plate boundary, relative to the coastlines of Africa and South America? -
This plate boundary is located in the middle of the Atlantic Ocean. 10.
Now click the other layers (seismicity and volcanoes) on and off so that you can see relationships between plate boundaries and these features. If you did not have the “plate boundary layer” available to you, how could you determine where this plate boundary was? Be sure to consider topography/bathymetry as well as the earthquake and volcano layers. List several ways and be specific.
-
The location of plate boundaries can be determined by the distribution patterns of earthquakes and volcanoes, as well as correlated shape between two different continents. Additionally, seafloor age, water depth, gravity, and heat flow in this region would indicate seafloor spreading, which is a result of divergent plate boundaries. Travel westward across the South American plate to its boundary with the Nazca plate
11.
Where is this plate boundary, relative to South America?
-
Located in the Pacific ocean, located roughly 2,700 miles from its western most boundary to
the continental margin of south America. 12.
If you did not have the “plate boundary layer” available to you, how could you determine where this plate boundary was? List several ways and be specific.
-
The distribution of volcanoes and earthquakes would indicate where the location of the boundaries are. However, a divergent boundary may not have many earthquakes and volcanoes to reference from, so it would be more accurate to use the ages of seafloor to determine the outline of the plate. Areas with younger seafloor would indicate where the basalts were forming from. F. Plate motion Motion across the mid-Atlantic ridge: the South American plate vs. the African plate
Turn off all the layers. Turn on the “Seafloor age” and the “Plate Boundary model” Google Earth (GE) layers. The “Seafloor age” layer shows the ages of volcanic rocks that have erupted and cooled to form the ocean floor. Focus on the Atlantic Ocean. Note that the age bands generally run parallel to the spreading ridges. Seafloor age is a critical piece of evidence for plate tectonics; these are used to reconstruct how ocean basins have developed over time and predict how they may evolve in the future.
13.
How many years does each colored band represent? -
10 M.a.
14.
On average, continental crust is 2 billion years old; the oldest rocks are 3.8 billion years old, and some of the grains in those rocks are even older. What is the age of the oldest seafloor? -
170-180 m.a.
On average, which is oldest – the continents or the ocean basins? -
The continents
15.
Find the South American plate, the African plate, and the Mid-Atlantic Ridge that marks the boundary between them. What happens to the age of the seafloor as distance increases away from the Mid-Atlantic Ridge?
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-
Seafloor age increases as you move further from the mid-atlantic ridge 16.
Is crust being created or destroyed at this plate boundary (and other spreading ridges)? -
Created 17.
Is this plate boundary divergent, convergent, or transform?
-
Divergent 18.
Focus on the northern Atlantic Ocean, near the east coast of the US and the northwest coast of Africa. How long ago did the northern Atlantic Ocean begin to open up or start spreading? Describe your reasoning.
-
The northern Atlantic Ocean began to open up around 170-180 m.a. due to the correlated sea floor ages along the east coast of north American and the northern coast of Africa.
19.
Did the northern Atlantic Ocean basin start opening at the same time as the southern Atlantic Ocean basin? How much older or younger is the northern Atlantic basin than the southern Atlantic basin? Describe your reasoning.
-
Rifting in the southern Atlantic ocean basin, appeared to have started 130-140 m.a., based on the sea floor ages along the southern most coasts eastern south American and western south Africa. Therefore, the south Atlantic ocean basin is about 40 m.a. younger. (based on an assignment designed by Laurel Goodell)