2.8: Introduction to Plate Tectonics

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Karla Panchuk
University of Saskatchewan

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Introduction to Plate Tectonics

The theory of plate tectonics—the idea that Earth’s surface is broken into large moving fragments, called plates—profoundly changed our perspective on how the Earth works. Before plate tectonic theory, we couldn’t answer questions like “How did that mountain range get there?” and “Why do earthquakes happen where they do?” This critical framework is also very recent—the papers that led to the widespread acceptance of plate tectonics were published at about the same time that we got cordless power tools, contact lenses, and satellite television.

Earth has 15 large tectonic plates (Figure 2.8.1), and numerous smaller ones. (A more detailed map of Earth’s tectonic plates can be found at here.) Tectonic plates move in a variety of directions and at a variety of speeds, although on average they move a few millimeters per year. In Figure 2.7.1, the black arrows show the direction of motion. The size of arrows indicates how fast the plate is moving. Plates with arrows going in more than one direction are rotating. Plate tectonic traffic is complicated!

The explanatory power of plate tectonic theory comes from what happens when plates interact along their margins. Plate boundary interactions (red arrows) include collisions (→ ←), separation (← →), or sliding along each other (↗ ↙).

A map of the world with large irregular shapes drawn on to show tectonic plates. — **Figure 2.8.1** Earth’s fifteen largest tectonic plates. Black arrows show the direction of plate motions. The length of the arrow indicates velocity. Red arrows show how plates move relative to each other. *Source: Steven Earle (2015) CC BY 4.0. view source Modified after U. S. Geological Survey (1996) Public Domain view original*

Before plate tectonic theory, we made observations but could only guess at mechanisms. It was like watching the hands on a clock and trying to guess what moves them. After plate tectonics it was like being able to open the clock and not only watch the gears turn, but realize for the first time that there are such things as gears. Plate tectonics not only explains why things have happened, but also allows us to predict what might happen in the future.

Plate tectonics is covered in more detail later, however the key point is that Earth’s outer layer consists of rigid plates that are constantly interacting with each other as they move around the Earth. The plates can move because they are floating on a layer of weak rock that deforms as the plates travel, much the same way the filling in a peanut butter and jelly sandwich allows you to slide the top layer of bread across the bottom layer.

Whether the plates move away from each other, collide, or just slide past each other determines things like the locations of mountain belts and volcanoes, where earthquakes happen, and the shapes and sizes of oceans and continents.

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