Seismic intensity scales

Last updated April 07, 2024

Seismic intensity scales categorize the intensity or severity of ground shaking (quaking) at a given location, such as resulting from an earthquake. They are distinguished from seismic magnitude scales, which measure the magnitude or overall strength of an earthquake, which may, or perhaps may not, cause perceptible shaking.

Intensity scales are based on the observed effects of the shaking, such as the degree to which people or animals were alarmed, and the extent and severity of damage to different kinds of structures or natural features. The maximal intensity observed, and the extent of the area where shaking was felt (see isoseismal map, below), can be used to estimate the location and magnitude of the source earthquake; this is especially useful for historical earthquakes where there is no instrumental record.

Ground shaking

Ground shaking can be caused in various ways (volcanic tremors, avalanches, large explosions, etc.), but shaking intense enough to cause damage is usually due to rupturing of the Earth's crust known as earthquakes. The intensity of shaking depends on several factors:

The "size" or strength of the source event, such as measured by various seismic magnitude scales.
The type of seismic wave generated, and its orientation.
The depth of the event.
The distance from the source event.
Site response due to local geology

Site response is especially important as certain conditions, such as unconsolidated sediments in a basin, can amplify ground motions as much as ten times.

Where an earthquake is not recorded on seismographs an isoseismal map showing the intensities felt at different areas can be used to estimate the location and magnitude of the quake.^[1] Such maps are also useful for estimating the shaking intensity, and thereby the likely level of damage, to be expected from a future earthquake of similar magnitude. In Japan this kind of information is used when an earthquake occurs to anticipate the severity of damage to be expected in different areas.^[2]

The intensity of local ground-shaking depends on several factors besides the magnitude of the earthquake,^[3] one of the most important being soil conditions. For instance, thick layers of soft soil (such as fill) can amplify seismic waves, often at a considerable distance from the source, while sedimentary basins will often resonate, increasing the duration of shaking. This is why, in the 1989 Loma Prieta earthquake, the Marina district of San Francisco was one of the most damaged areas, though it was nearly 100 kilometres (60 mi) from the epicenter.^[4] Geological structures were also significant, such as where seismic waves passing under the south end of San Francisco Bay reflected off the base of the Earth's crust towards San Francisco and Oakland. A similar effect channeled seismic waves between the other major faults in the area.^[5]

History

The first simple classification of earthquake intensity was devised by Domenico Pignataro in the 1780s.^[6] The first recognisable intensity scale in the modern sense of the word was drawn up by P.N.G. Egen in 1828. However, the first modern mapping of earthquake intensity was made by Robert Mallet, an Irish engineer who was sent by Imperial College, London, to research the December 1857 Basilicata earthquake, also known as The Great Neapolitan Earthquake of 1857.^[7] The first widely adopted intensity scale, the Rossi–Forel scale , was introduced in the late 19th century as a 10 grade scale.^[8] In 1902, Italian seismologist Giuseppe Mercalli, created the Mercalli Scale, a new 12-grade scale. A very significant improvement was achieved, mainly by Charles Francis Richter during the 1950s, when (1) a correlation was found between seismic intensity and the Peak ground acceleration - PGA (see the equation that Richter found for California).^[9] (2) a definition of the strength of the buildings, and a subdivision into groups (called type of buildings) was made. Then, the evaluation of the seismic intensity was based upon the damage grade to a given type of structure. That gave the Mercalli Scale, as well as the followed European MSK-64 scale, the quantitative element, which represents the vulnerability of the building's type.^[10] Since then, that scale was called the Modified Mercalli intensity scale - MMS and the evaluations of the Seismic Intensities became more reliable.^[11]

In addition, more intensity scales have been developed and are used in different parts of the world:

Country/Region	Seismic intensity scale used
China	Liedu scale (GB/T 17742–1999)
Europe	European Macroseismic Scale (EMS-98)^[12]
Hong Kong	Modified Mercalli scale (MM)^[13]
India	Medvedev–Sponheuer–Karnik scale
Indonesia	Modified Mercalli scale (MM)^[14]
Israel	Medvedev–Sponheuer–Karnik scale (MSK-64)
Japan	JMA Seismic Intensity Scale
Kazakhstan	Medvedev–Sponheuer–Karnik scale (MSK-64)
Philippines	PHIVOLCS Earthquake Intensity Scale (PEIS)
Russia	Medvedev–Sponheuer–Karnik scale (MSK-64)
Taiwan	Central Weather Administration seismic intensity scale ^[15]
United States	Modified Mercalli scale (MM)^[16]

Notes

↑ Bormann, Wendt & Di Giacomo 2013 , §3.1.2.1.
↑ Doi 2010.
↑ Bolt 1993 , p. 164 et seq..
↑ Bolt 1993 , pp. 170–171.
↑ Bolt 1993 , p. 170.
↑ Alexander 1993 , p. 28.
↑ Mallet 1862.
↑ Bolt 1988 , p. 147.
↑ $\log a={\frac {I}{3}}-0.5$ where $a$ is the PGA for that given site with value of (cm/sec²) and $I$ is the Intensity value for that site. see: Richter 1958 , p. 140.
↑ Lapajne 1984.
↑ Bolt 1988 , p. 146–152.
↑ "The European Macroseismic Scale EMS-98". Centre Européen de Géodynamique et de Séismologie (ECGS). Retrieved 2013-07-26.
↑ "Magnitude and Intensity of an Earthquake". Hong Kong Observatory. Retrieved 2008-09-15.
↑ "Skala MMI (Modified Mercalli Intensity)" (in Indonesian). Meteorology, Climatology, and Geophysical Agency . Retrieved 2022-09-28.
↑ "Earthquake Preparedness and Response". Central Weather Bureau. Retrieved 2018-04-06.
↑ "The Severity of an Earthquake". U.S. Geological Survey. Retrieved 2012-01-15.

Sources

Alexander, David (1993), Natural Disasters (1 ed.), Springer Science+Business Media, ISBN 978-0-412-04741-1 .

Bolt, Bruce A. (1988), Earthquakes (2 ed.), W. H. Freeman and Company, ISBN 978-0716718741 .

Bolt, Bruce A. (1993), Earthquakes and geological discovery , Scientific American Library, ISBN 0-7167-5040-6 .

Bormann, P.; Wendt, S.; Di Giacomo, D. (2013), "Chapter 3: Seismic Sources and Source Parameters" (PDF), in Bormann (ed.), New Manual of Seismological Observatory Practice 2 (NMSOP-2), doi:10.2312/GFZ.NMSOP-2_ch3 .

Doi, K. (2010), "Operational Procedures of Contributing Agencies" (PDF), Bulletin of the International Seismological Centre, 47 (7–12): 25, ISSN 2309-236X . Also available here (sections renumbered).

Lapajne, Janez (1984), "The MSK-78 intensity scale and seismic risk", Engineering Geology, 20 (1–2): 105–112, doi:10.1016/0013-7952(84)90047-4 .

Mallet, Robert (1862), Great Neapolitan Earthquake of 1857: The First Principles of Observational Seismology as Developed in the Report to the Royal Society of London of the Expedition Made by Command of the Society Into the Interior of the Kingdom of Naples, to Investigate the Circumstances of the Great Earthquake of December 1857, vol. 1, Chapman & Hall .

Richter, Charles F. (1958), Elementary Seismology (1 ed.), London & San Francisco: W. H. Freeman and Company .

External links

USGS ShakeMap Providing near-real-time maps of ground motion and shaking intensity following significant earthquakes.

Related Research Articles

An earthquake – also called a quake, tremor, or temblor – is the shaking of the Earth's surface resulting from a sudden release of energy in the lithosphere that creates seismic waves. Earthquakes can range in intensity, from those so weak they cannot be felt, to those violent enough to propel objects and people into the air, damage critical infrastructure, and wreak destruction across entire cities. The seismic activity of an area is the frequency, type, and size of earthquakes experienced over a particular time. The seismicity at a particular location in the Earth is the average rate of seismic energy release per unit volume.

The Modified Mercalli intensity scale measures the effects of an earthquake at a given location. This is in contrast with the seismic magnitude usually reported for an earthquake.

The Japan Meteorological Agency (JMA) Seismic Intensity Scale is a seismic intensity scale used in Japan to categorize the intensity of local ground shaking caused by earthquakes.

The moment magnitude scale is a measure of an earthquake's magnitude based on its seismic moment. M_w  was defined in a 1979 paper by Thomas C. Hanks and Hiroo Kanamori. Similar to the local magnitude/Richter scale (M_L ) defined by Charles Francis Richter in 1935, it uses a logarithmic scale; small earthquakes have approximately the same magnitudes on both scales. Despite the difference, news media often use the term "Richter scale" when referring to the moment magnitude scale.

Peak ground acceleration (PGA) is equal to the maximum ground acceleration that occurred during earthquake shaking at a location. PGA is equal to the amplitude of the largest absolute acceleration recorded on an accelerogram at a site during a particular earthquake. Earthquake shaking generally occurs in all three directions. Therefore, PGA is often split into the horizontal and vertical components. Horizontal PGAs are generally larger than those in the vertical direction but this is not always true, especially close to large earthquakes. PGA is an important parameter for earthquake engineering, The design basis earthquake ground motion (DBEGM) is often defined in terms of PGA.

In seismology, strong ground motion is the strong earthquake shaking that occurs close to a causative fault. The strength of the shaking involved in strong ground motion usually overwhelms a seismometer, forcing the use of accelerographs for recording. The science of strong ground motion also deals with the variations of fault rupture, both in total displacement, energy released, and rupture velocity.

The Medvedev–Sponheuer–Karnik scale, also known as the MSK or MSK-64, is a macroseismic intensity scale used to evaluate the severity of ground shaking on the basis of observed effects in an area where an earthquake transpires.

Seismic magnitude scales are used to describe the overall strength or "size" of an earthquake. These are distinguished from seismic intensity scales that categorize the intensity or severity of ground shaking (quaking) caused by an earthquake at a given location. Magnitudes are usually determined from measurements of an earthquake's seismic waves as recorded on a seismogram. Magnitude scales vary based on what aspect of the seismic waves are measured and how they are measured. Different magnitude scales are necessary because of differences in earthquakes, the information available, and the purposes for which the magnitudes are used.

The 1857 Basilicata earthquake occurred on 16 December in the Basilicata region of Italy southeast of the city of Naples. The epicentre was in Montemurro, on the western border of the modern province of Potenza. Several towns were destroyed, and there were around 11,000 fatalities according to official sources, but unofficial estimates suggest that as many as 19,000 died. At the time it was the third-largest known earthquake and has been estimated to have been of magnitude 7.0 on the moment magnitude scale.

Body-waves consist of P-waves that are the first to arrive, or S-waves, or reflections of either. Body-waves travel through rock directly.

The Richter scale, also called the Richter magnitude scale, Richter's magnitude scale, and the Gutenberg–Richter scale, is a measure of the strength of earthquakes, developed by Charles Francis Richter in collaboration with Beno Gutenberg, and presented in Richter's landmark 1935 paper, where he called it the "magnitude scale". This was later revised and renamed the local magnitude scale, denoted as ML or M_L .

The 1868 Hayward earthquake occurred in the San Francisco Bay Area, California, United States on October 21. With an estimated moment magnitude of 6.3–6.7 and a maximum Mercalli intensity of IX (Violent), it was the most recent large earthquake to occur on the Hayward Fault Zone. It caused significant damage and a number of deaths throughout the region, and was known as the "Great San Francisco earthquake" prior to the 1906 San Francisco earthquake and fire.

The 1965 Puget Sound earthquake occurred at 08:28 AM PDT on April 29 within the Puget Sound region of Washington state. It had a magnitude of 6.7 on the moment magnitude scale and a maximum perceived intensity of VIII (Severe) on the Mercalli intensity scale. It caused the deaths of seven people and about $12.5–28 million in damage. There were no recorded aftershocks.

In seismology, an isoseismal map is used to show lines of equally felt seismic intensity, generally measured on the Modified Mercalli scale. Such maps help to identify earthquake epicenters, particularly where no instrumental records exist, such as for historical earthquakes. They also contain important information on ground conditions at particular locations, the underlying geology, radiation pattern of the seismic waves, and the response of different types of buildings. They form an important part of the macroseismic approach, i.e. that part of seismology dealing with noninstrumental data. The shape and size of the isoseismal regions can be used to help determine the magnitude, focal depth, and focal mechanism of an earthquake.

The 1865 Memphis earthquake struck southwest Tennessee near the Mississippi River in the United States on August 17 that year. Soon after the M_fa 5.0 earthquake hit, observers said the earth appeared to undulate and waves formed in nearby rivers. The force of the earthquake felled and cracked chimneys in Memphis and New Madrid, Missouri on the other side of the Mississippi. Shaking from the earthquake spread as far as St. Louis, Missouri; Jackson, Mississippi; and Illinois. Apart from the 1811–12 New Madrid earthquakes, only three major events have struck the state of Tennessee, in 1843, 1865, and 1895. Several minor events have taken place as well.

The 1872 North Cascades earthquake occurred at 9:40 p.m. local time on December 14 in central Washington Territory. A maximum Mercalli intensity of VIII (Severe) was assessed for several locations, though less intense shaking was observed at many other locations in Washington, Oregon, and British Columbia. Some of these intermediate outlying areas reported V (Moderate) to VII shaking, but intensities as high as IV (Light) were reported as far distant as Idaho and Montana. Due to the remote location of the mainshock and a series of strong aftershocks, damage to structures was limited to a few cabins close to the areas of the highest intensity.

The 1892 Vacaville–Winters earthquakes occurred in northern California as a large doublet on April 19 and April 21. Measured on a seismic scale that is based on an isoseismal map or the event's felt area, the 6.4 M_la and 6.2 M_la  events were assigned a maximum Mercalli intensity of IX (Violent), and affected the North Bay and Central Valley areas. The total damage was estimated to be between $225,000 and 250,000 and one person was killed. No evidence of fault movement on the surface of the ground was observed as a result of either of the strong shocks. Both occurred in the domain of the San Andreas strike-slip system of faults, but their focal mechanism is uncertain.

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[1] Bormann, Wendt & Di Giacomo 2013 , §3.1.2.1.

[2] Doi 2010.

[3] Bolt 1993 , p. 164 et seq..

[4] Bolt 1993 , pp. 170–171.

[5] Bolt 1993 , p. 170.

[6] Alexander 1993 , p. 28.

[7] Mallet 1862.

[8] Bolt 1988 , p. 147.

[9] $\log a={\frac {I}{3}}-0.5$ where $a$ is the PGA for that given site with value of (cm/sec²) and $I$ is the Intensity value for that site. see: Richter 1958 , p. 140.

[10] Lapajne 1984.

[11] Bolt 1988 , p. 146–152.

[GFZ-12] "The European Macroseismic Scale EMS-98". Centre Européen de Géodynamique et de Séismologie (ECGS). Retrieved 2013-07-26.

[HK_observatory-13] "Magnitude and Intensity of an Earthquake". Hong Kong Observatory. Retrieved 2008-09-15.

[14] "Skala MMI (Modified Mercalli Intensity)" (in Indonesian). Meteorology, Climatology, and Geophysical Agency . Retrieved 2022-09-28.

[15] "Earthquake Preparedness and Response". Central Weather Bureau. Retrieved 2018-04-06.

[USGS_General_Interest_Publication-16] "The Severity of an Earthquake". U.S. Geological Survey. Retrieved 2012-01-15.

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