1934 Hansel Valley earthquake

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The 1934 Hansel Valley earthquake occurred on March 12 at approximately 8:05 a.m. MST with a moment magnitude of 6.6 and a maximum Mercalli intensity of VIII (Severe). The shock originated in the Hansel Valley at the north end of the Great Salt Lake in Utah in the United States. Damage was mostly confined to vulnerable buildings, and two people died. The dip-slip (normal) fault that generated the shock ruptured the surface of the ground and other geologic features were documented. A large aftershock occurred three hours after the initial event and may have caused additional damage.

1934 Hansel Valley earthquake
1934 Hansel Valley earthquake is located in Utah
Salt Lake City
Salt Lake City
1934 Hansel Valley earthquake
UTC time1934-03-12 15:05:41
ISC event904837
USGS-ANSSComCat
Local dateMarch 12, 1934 (1934-03-12)
Local time08:05 a.m. MST
MagnitudeMw 6.6
Depth10.0 km (6.2 mi)
Epicenter41°42′N 112°48′W / 41.7°N 112.8°W / 41.7; -112.8
TypeNormal
Areas affectedUtah, southern Idaho
Max. intensityMMI VIII (Severe)
AftershocksMw 5.9 Mar 12 at 18:20 UTC
Casualties2 dead

Tectonic setting

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Situated in southern Nevada, Utah, Idaho, western Wyoming and western Montana, the Intermountain Seismic Belt (ISB) is a region of crustal stretching and intraplate deformation. This results in a 810 mi (1,300 km) zone of active tectonics, with uplift in the mountains and comparative subsidence in the valleys. This area follows California and Western Nevada in the lower 48 states in terms of seismic risk.[1]

Within the ISB, the Basin and Range Province is a region of extensional tectonics and lays between the Sierra Nevada in the west and the Colorado Plateau in the east. It comprises north-trending mountains that are mostly uniform in height and are separated by flat valleys with mostly consistent widths. The prevalent fault type in this area is dip-slip (normal).[2]

Earthquake

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The magnitude 6.6 shock occurred on an unnamed and north-trending normal fault that slipped over a distance of 6.8 miles (11 km). Surface rupture was present but may not have reached the surface over the entire length. The maximum vertical offset was 1 foot 8 inches (.5 m).[3]

Aftershocks

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Several hundred aftershocks occurred over the following days and weeks. The most significant of these was a magnitude 5.9 shock that took place a little over three hours after the mainshock. The damage that resulted from this less severe event could not be distinguished from the initial one, but it was also felt in Idaho, Nevada, and Wyoming.[4][5]

Several other events made the record books at the University of Utah. On March 15, there were two shocks of magnitude 5.1 and 4.8 with assumed (as opposed to observed) intensities of VI (Strong) and V (Moderate). Around one month later on April 14 there was another earthquake of magnitude 5.6 with an observed intensity of VII (Very strong) and on May 6 another one also measured at 5.6 with an intensity of VI (all in Richter magnitude).[6]

Intensity

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Mainshock

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The mainshock is depicted by a United States Geological Survey isoseismal map with a relatively small zone with the maximum felt intensity of VIII (Severe) at the north end of the Great Salt Lake. Salt Lake City and the extreme southern portion of Idaho lay in the intensity VI (Strong) zone and Pocatello, Idaho lay just to the north within the intensity V (Moderate) zone.[5]

Aftershock

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The most significant aftershock took place on the same day as the mainshock. The National Geophysical Data Center declared that its intensity peaked at VI (Strong) only in Utah at Kosmo and Monument. It was felt with an intensity of V (Moderate) in Logan and Ogden, both in Utah. Pocatello and Twin Falls, Idaho both reported an intensity of IV (Light), as did Salt Lake City. At 400 miles (644 km) distant from the epicentral area, it was felt in Cheyenne, Wyoming with an intensity of III (Weak).[7]

Damage

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The meizoseismal area was mostly unpopulated, but there were a few small towns that experienced damage to mostly weaker structures. Cracked walls and damage to chimneys was reported in Logan, Hooper, Kelton, Kosmo, Locomotive Springs, Monument, and Snowville. At least two people were killed.[5]

Ground effects

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Following a 20th-century field survey of the affected areas, features such as large rock slides, previously dormant wells and springs, and an increase in the flow of an oil seep were documented. The surveyor reported that in areas where surface faulting was present, it was discontinuous and it did not occur in bedrock and was mostly observed in unconsolidated rocks or salt flats.[8]

In the 21st-century, seismologists were able to validate that the surface ruptures were of tectonic origin (as opposed to secondary surface effects) using a vertical seismic profile process. This modern technique uses various instruments placed in boreholes along an area of interest, which gather data from an artificial seismic source. The study showed that the slip was vertical near the surface, but horizontal at depth, indicating a transtensional environment.[9]

Aftermath

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The Salt Lake City and County Building was dedicated in 1894 well before earthquake engineering developed. For some time it was Utah's tallest building and it experienced minor damage during earthquakes, including the 1934 shock. The building was eventually retrofitted with a seismic base isolation system to avoid resonance of the building during future events.[10]

See also

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References

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  1. ^ Arabasz, W. J.; Smith, R. B. (1979). "Earthquake Studies in Utah 1850 to 1978". In Arabasz, W. J.; Smith, R. B.; Richins, W. D. (eds.). Introduction: What You've Always Wanted to Know About Earthquakes in Utah. University of Utah. pp. 2, 3, 5.
  2. ^ Yeats, R. (2012), Active Faults of the World, Cambridge University Press, pp. 124, 125, 131, ISBN 978-0-521-19085-5
  3. ^ Yeats, R. S.; Sieh, K. E.; Allen, C. R. (1997). The Geology of Earthquakes. Oxford University Press. p. 477. ISBN 978-0-19-507827-5.
  4. ^ Arabasz, W. J. (January 10, 2019). Revised Historical Earthquake Catalog for the Utah Region, 1850 – June 1962. University of Utah. Archived from the original on April 15, 2021.
  5. ^ a b c Stover, C. W.; Coffman, J. L. (1993), Seismicity of the United States, 1568–1989 (Revised), U.S. Geological Survey Professional Paper 1527, United States Government Printing Office, pp. 368, 369
  6. ^ Richins, W. D. (1979). "Earthquake Data for the Utah Region, 1850 to 1978". In Arabasz, W. J.; Smith, R. B.; Richins, W. D. (eds.). Introduction: What You've Always Wanted to Know About Earthquakes in Utah. University of Utah. p. 128.
  7. ^ Earthquake Intensity Database 1638–1985, National Geophysical Data Center, retrieved September 2, 2022
  8. ^ Neuman, F. (1936), United States earthquakes, 1934, Serial No. 593, United States Government Printing Office, pp. 43–48
  9. ^ Bruno, P. P. G.; DuRoss, C. B.; Kokkalas, S. (2017). "High-resolution seismic profiling reveals faulting associated with the 1934 Ms 6.6 Hansel Valley earthquake (Utah, USA)". Geological Society of America Bulletin: B31516.1. doi:10.1130/b31516.1. ISSN 0016-7606.
  10. ^ Bailey, J. S.; Allen, E. W. (1988), "Seismic Isolation Retrofitting: Salt Lake City and County Building", APT Bulletin, 20 (2): 33–44, doi:10.2307/1494249, JSTOR 1494249

Further reading

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