Other Plate Tectonics Info:
Plate Tectonics Intro
Plate Tectonics History
Other Implications

More links to web sites that contain information about Plate Tectonics can be accessed through the Links Page of this web site.  The figures shown here were taken and/or modified from the USGS Plate Tectonics web pages.

Questions that you should be able to answer at the end of the Plate Tectonics lecture:

  1. What are the ways in which the exterior and interior of the world is depicted?
  2. What is the basic structure of the Earth?
  3. You should be able to draw the Earth's basic structure, with labels of composition and physical properties.
  4. What are the basic parts of the definition of plate tectonics?
  5. What part of the Earth is the "plate"?
  6. What are the different kinds of plate boundaries?
  7. What are the different kinds of convergent boundaries?
  8. What are some examples of each kind of plate boundaries?
  9. What characteristics are present at each kind of plate boundary?
  10. How can each plate boundary be recognized and identified?
  11. You should be able to draw each type of plate boundary, with labels of the characteristics.
  12. How fast do plates move?
Plate Tectonics
First, the way that we look at the Earth.  Geologists look at, and depict, the Earth in a wide variety of ways, and it is important for you to understand these and be able to use them.



Of all of these, the most familiar is probably the Map View.  This is a generally 2-dimensional view of the surface of the Earth.  In the one shown at left, you can see 3 rivers, and you might also (in other maps) see roads, geographic boundaries, rock types, and really, anything that can be depicted at the surface of the Earth.


The problem is that we can't see anything about changes in elevation on that map view.  If, for instance, you walked from the lower left to the lower right of that map, you'd walk down to the bottom of a river valley, and then back out.  We show that, by using a Profile, which shows elevation changes along a line.  If you've ever gone on a long hike using a trail map, you might see a profile printed on the side of the map which shows not only changes in elevation, but changes in steepness, to help you decide whether you need sandals, sneakers, hiking boots, or climbing gear.


Again, there's a problem with a profile:  We can't see what's going on below the surface.  To see that (or to show that you've figured that out), you'd use a Cross Section, which shows not only what's happening in the profile, but below the surface.  They are very useful.  For instance, in this case, we can see that there are 3 layers, that they've been folded (probably through a tectonic collision), and that there is a fault cutting through all of it.  Not only that, but you can get an idea of geologic history as well.  In this case, the orange, bottom, layer is oldest, then the green-blue (teal) layer, and finally the purple layer.  After that, the layers were folded or crumpled (because they originally get deposited in flat-lying layers), and then finally the fault cut through everything.


But again, we're missing something - the surface.  Our last, most complex and most comprehensive way of looking at the Earth (although not always necessary or the best way) is a "Block Model".  In this we have one or more cross sections (in the one shown in the upper left, we have 2), as well as map view.  We can use this to get a very complete idea of what's happening in this view of the Earth.

One last thing: It's not just geologists that use all of these.  Meteorologists, Oceanographers, even Astronomers all use these views, to look at the atmosphere, the ocean, even the interior of stars.  Even biologists use them.  You've probably seen cross sections of the body, and a photograph of an organism is a kind of a map.
For more information about these ways of looking at the Earth, click here

Next, the Earth's Structure:

(Is this a map, profile, cross section, or block model?)
 What is a plate?  It is more than just the crust, but a layer (the LITHOSPHERE) composed of crust (oceanic and/or continental) and uppermost mantle:
(note: figure taken from USGS; click on figure to find website)
This layer is about 150 km thick, and is rigid (hence the name litho = rock sphere), and rides on the soft layer below, the asthenosphere, which is capable of flowing.  The oceanic and/or continental crust that is on the top of the plate merely rides as a passive passenger on the plate, rather than having the continental crust forced through the oceanic crust as Wegener envisioned.

Click here for a discussion of this diagram.
Go to this link, and read it carefully before returning here.

Notes about the above image:

  1. The image above is from the United States Geologic Survey (USGS) web site on Plate Tectonics, as are many of the images below.  This is an EXCELLENT web site and I encourage you to go take a look at that website.  It has a lot of great information in it, and we will return to it many times.  If you want to look at the web site, click on the image.
  2. For most of the images that I've "borrowed" from other web sites, I'll include a link to the original website.  In this case, so you can go see it, but in most cases, as a reference to where I originally got it in the first place.
  3. The above image is a MODEL - that means that, like much of what you will learn in not only this class but in ALL of your classes, it is a simplification of reality, that, in this case, that allows us to understand what is happening in the Earth.  There may be differences between what we will see in reality, but they will be minor.
  4. Make sure that you can reproduce this image.  Not the artwork, but the concepts and properties that are shown in it.
  5. Make SURE that you click on the discussion of the diagram and learn the material on that web page.

Now that we understand the Earth's structure, we can look at Plate Tectonics:
The basic parts of Plate Tectonics are:

  1. "Plates" are rigid, spherical caps covering the earth's surface that move relative to one another.  A plate may be covered with only Oceanic Crust, only Continental Crust, or a combination of Continental and Oceanic Crust.  But within a Plate, all parts of the plate move together.
  2. Deformation of plates occurs only at their "Margins" (or "Boundaries").  What kinds of deformation? 
  3. There are ONLY 3 types of motion between plates: towards each other, away from each other, and sliding side to side.
    Because of this, there are 3 basic types of Plate Tectonic Margins, based on the type of relative motion between the plates.
    Make sure you know how to draw them.  Doing so will help you understand the processes and features at each.
    Click on the drawing link to each boundary type to see how to do this.  And when you click on the "how to draw" links below, you'll be able to download a blank diagram that you can use to practice drawing the different margin types, which will help you understand them.

    1. Divergent - where the plates are moving apart at that margin (see figure below).
    2. Transform - where the plates are moving in opposite directions along the direction of the margin (see figure below).
    3. Convergent - where the plates are moving towards one another at that margin (see figures below).
Geographic examples of each may be found in your textbook (note: the figures above are from the USGS web site mentioned in the links page.  Click on the images to access the web page.).

One last issue:  How fast do plates move?
The first question you might have when you think about that is, how do we know?
  1. Through a number of different ways, we can find the age of different parts of oceanic crust (which is all formed at Mid-Ocean Ridges).
  2. We can also calculate current plate movement rates by using high-precision GPS from one year to the next, on different continents, and watch how the distances between them change.  We get similar values as we calculate by using  multi-million year timescales.  The results tell us 2 things:
    1. The year to year rates are pretty continuous for millions of years, and
    2. Tha AVERAGE rate of plate motion worldwide is about 5 cm/yr (~2 inches/yr) and varies from 2 to 20 cm/yr.
  3. How fast is 5 cm/yr?  If you measure how fast your fingernails grow (mark your thumbnail and watch it grow!), it's about 5 cm/yr.

Finally, click here to see a bunch of the features you will be answering questions about in the Canvas exercise on this lecture.

Suppose I asked you what kind of boundary a particular place is.  What would you look for?

Other Plate Tectonics Info:
Plate Tectonics Intro
Plate Tectonics History
Other Implications

More links to web sites that contain information about Plate Tectonics can be accessed through the Links Page of this web site.  The figures shown here were taken and/or modified from the USGS Plate Tectonics web pages.