2. Where do earthquakes occur?

2.1 Plate Boundary Earthquakes

As detailed in Chapter 1A, bands of earthquakes trace out plate boundaries (Figure 1B.2.1, colored dots). The depths of earthquakes and the width of the band depend on the type of plate boundary. Mid-ocean ridges and transform margins have shallow earthquakes (usually less than 30 km deep) in narrow bands close to plate margins. Subduction zones have earthquakes at a range of depths, with the shallowest earthquakes occurring near or on the plate boundary and getting progressively deeper into the overriding plate side of the boundary as earthquakes occur all along the subducting plate which extends beneath the overriding plate. Wide swaths of scattered earthquakes may correspond to continent-continent collision zones.

Plate boundary map with earthquakes shown as colored dots. Earthquakes are color coded and have patterns along plate boundaries as described in the figure caption.
Figure 1B.2.1 Earthquakes greater than magnitude 5, from 2000 to 2008. Bands of earthquakes mark tectonic plates. Narrow bands with shallow earthquakes (marked in red) indicate transform boundaries or mid-ocean ridge divergent boundaries. Wider bands with earthquakes at a range of depths are subduction zones. Wide bands of scattered earthquakes mark continent-continent convergent margins (e.g., between the Indian and Eurasian plates). Source: Karla Panchuk (2023), CC BY-NC-SA 4.0 found here, adapted from base map by Lisa Christiansen, Caltech Tectonics Observatory (2008). National Science Foundation. Image source.Plate and ocean basin labels added.

Most earthquakes occur associated with a plate boundary. However, earthquakes can occur in areas not associated with plate boundaries as well.

2.2 Intraplate Earthquakes

Intraplate earthquakes (within-plate earthquakes) are those that occur away from plate boundaries. Some intraplate earthquakes are related to human activities. When humans trigger earthquakes it is referred to as induced seismicity. These are commonly a result of mining activity as excavating can change the stress in surrounding rocks triggering an earthquake or due to hydraulic fracturing operations where injecting high pressure water mixtures can increase stress along existing faults causing them to slip. Human induced seismicity tends to be smaller in magnitude (less than 4).

Intraplate earthquakes not related to human activities often occur along ancient rift zones. A well-known example of this in North America is the New Madrid Seismic Zone. It is the most naturally seismically active area east of the Rocky Mountains and is in the Mississippi River Valley area (Figure 1B.2.2).

Map of the New Madrid Seismic Zone. The New Madrid Seismic Zone is along the Mississippi River valley from Missouri/Kentucky through to Mississippi/Arkansas. The earthquakes, shown as dots on the map, cluster in a line through the river valley in this area.
Figure 1B.2.2.  Map of the New Madrid Seismic Zone. Earthquakes with magnitudes equal to or larger than 2.5 are shown by the yellow dots. Localities where geologists have found and published their findings on faults or evidence of large earthquakes are shown by red stars. Source: USGS (n.d.) Public domain. Found here.

The faults that underlie the New Madrid Seismic Zone are the result of a failed continental rift through the area 600 million years ago. At that time North America was being pulled apart, much like Eastern Africa is today, creating faults and a long linear continental rift valley. That rifting stopped before North America pulled apart enough to create an ocean basin, and the rift valley landscape was then filled in with sediments eroded off the land and brought to the area by rivers (Figure 1B.2.3).

Since 1974, thousands of small to moderate earthquakes have been recorded in this area. While the faults themselves are not visible on the ground surface as they are covered with sediment, the pattern of earthquake epicenters marks out the fault locations.

The New Madrid Seismic Zone is very far from any present-day active plate boundaries, but the tectonic forces from plate boundaries are transmitted into the interiors of continents creating pressure that can reactivate these ancient faults and cause earthquakes. It is much easier to cause rocks to slip along an existing fault like those underlying the New Madrid Seismic Zone, than it is to make new faults altogether!

Diagram showing a geologic model of the New Madrid region.  The Mississippi River Valley in this area is underlain by old rift faults (faults from divergent boundary/rifting action). These faults are not visible on the surface as they are covered over with rocks and sediments. The rift faults are located in the area under the Mississippi River valley.
Figure 1B.2.3 Geologic model of the New Madrid Seismic Zone. Buried rift faults are shown in cross section view (front of block) as dark lines. Note those lines do not extend to the surface (top of block). These are covered over with sedimentary rocks in the Mississippi river area. The white patterned area on the map view (top of block) shows the area of the buried rift faults, which corresponds to the zone of recorded earthquakes. Source: USGS (n.d.) Public domain. Found here.

Refresher on earthquake patterns and plate boundaries

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