Categorized | Earthquake, Featured, Sci-Tech, Volcano

Volcano Watch: How big is that earthquake? Why magnitudes sometimes change

(Volcano Watch is a weekly article written by scientists at the U.S. Geological Survey’s Hawaiian Volcano Observatory.)

The Kalāhikiola Congregational Church in Kapa‘au was extensively damaged on October 15, 2006, by two earthquakes (magnitudes 6.7 and 6.0) off the northwest coast of Hawaiʻi Island. The earthquakes were felt throughout the State of Hawaii, but the greatest damage occurred in the North Kona and Kohala Districts of the Island of Hawaiʻi.  An example of a seismogram (bottom of photo) illustrates the relation between the amplitude and duration of shaking, which is used by seismologists to compute earthquake magnitudes. USGS photo.

The Kalāhikiola Congregational Church in Kapa‘au was extensively damaged on October 15, 2006, by two earthquakes (magnitudes 6.7 and 6.0) off the northwest coast of Hawaiʻi Island. The earthquakes were felt throughout the State of Hawaii, but the greatest damage occurred in the North Kona and Kohala Districts of the Island of Hawaiʻi. An example of a seismogram (bottom of photo) illustrates the relation between the amplitude and duration of shaking, which is used by seismologists to compute earthquake magnitudes. USGS photo.

Characterizing earthquakes is one of the most important activities we do at the USGS Hawaiian Volcano Observatory (HVO). Seismicity helps us monitor the “pulse” of volcanoes and can be a first indication of an impending eruption.

Earthquakes also pose a hazard in their own right, and the entire State of Hawaii is at risk from damaging earthquakes. They occur abruptly, so we must be vigilant and prepared.

HVO posts preliminary information about earthquake location and size (magnitude) as soon as possible after one occurs. Later, we update the information as more data becomes available. Sometimes the reported magnitude changes during this process.

When the earth shakes, vibrating seismic waves radiate outward from the source. These waves are picked up by sensitive instruments called seismometers, which are located across the state. Seismic data is relayed in near real-time to HVO, where computers trained to look for earthquake patterns keep watch around the clock. When four or more stations detect an earthquake, the computer automatically estimates the location and magnitude of the event.

If the earthquake magnitude is above 3.0, the computer posts the information to HVO’s website (http://hvo.wr.usgs.gov) without human intervention. The USGS Earthquake Notification Service (https://sslearthquake.usgs.gov/ens/) then alerts subscribers. This generally happens within five minutes of the earthquake.

HVO’s seismologists then spring to action to review the data. They recalculate the earthquake parameters and, if needed, overwrite the previously posted automatic ones. For magnitude-4.0 and higher earthquakes, we complete our manual review within two hours and issue a news release. Events smaller than magnitude-4.0 are reviewed routinely within a few days.

Upon review by a seismologist, the earthquake’s magnitude can go up or down by a few tenths. Different groups, such as the Pacific Tsunami Warning Center and the USGS National Earthquake Information Center, might also report slightly different magnitudes. To understand these differences, let’s review what magnitude means.

The concept of earthquake magnitude dates back to 1935, when Charles Richter created a way to compare the relative sizes of earthquakes in southern California. He measured how the amplitude of shaking recorded by seismometers decreased with distance from an earthquake. Using the logarithm of the maximum amplitude, Richter was able to derive a scale that conveyed the wide range of earthquake sizes, which can vary by several orders of magnitude (hence the name). For example, on this scale, the amplitude of a magnitude-4.0 earthquake is ten times higher than that of a magnitude-3.0 earthquake.

Today, there are numerous types of earthquake magnitudes that take advantage of advances in seismic instrumentation and cover a wide range of situations. For earthquakes higher than about magnitude-5.5, the most common measure of magnitude is called moment magnitude, which relates fundamentally to the energy released by an earthquake’s fault motion. For every 0.2 increase in moment magnitude, the energy doubles. For example, a magnitude-6.2 earthquake releases roughly twice as much energy as a magnitude-6.0 event.

For smaller earthquakes, like those that happen daily in Hawaii, HVO computes two types of magnitude based on either the duration or amplitude of the shaking recoded by seismometers. Duration magnitude tends to work better for smaller earthquakes (less than about magnitude-2.0) that are located shallower than 20 km (12 mi) beneath the surface. Amplitude magnitude, which is a modern-day formulation of Richter’s magnitude, works better for local earthquakes with magnitudes between about 2.0 and 5.5.

Any reported magnitude is actually an average of values computed for each seismometer that recorded the earthquake. These values vary depending on distance, direction, instrument, and the type of material type along the seismic wave’s path. HVO seismologists evaluate which stations provide the most reliable and objective magnitude estimates, average them together, and select either duration or amplitude as the preferred magnitude type for each event.

Magnitudes can change following a seismologist’s review and analysis of the computer’s automatic magnitude assignment. This process provides the best information available at any given time and offers a window into how the science of real-time seismology unfolds.

What matters more than a number, however, is what you do if you feel shaking during an earthquake. On October 20, we encourage you to take part in the world’s largest earthquake preparedness exercise by practicing “Drop, Cover, and Hold On!” during the Great Hawai‘i ShakeOut (http://shakeout.org/hawaii).

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