Depth of focus (tectonics) explained

In seismology, the depth of focus or focal depth is the depth at which an earthquake occurs. Earthquakes occurring at a depth of less than 70km (40miles) are classified as shallow-focus earthquakes, while those with a focal depth between 70km (40miles) and 300km (200miles) are commonly termed mid-focus or intermediate-depth earthquakes.[1] In subduction zones, where older and colder oceanic crust sinks under another tectonic plate, deep-focus earthquakes may occur at much greater depths in the mantle, ranging from 300km (200miles) up to 700km (400miles).[2] [3]

The cause of deep-focus earthquakes is still not entirely understood since subducted lithosphere at that pressure and temperature regime should not exhibit brittle behavior. A possible mechanism for the generation of deep-focus earthquakes is faulting caused by olivine undergoing a phase transition into a spinel structure,[4] with which they are believed to be associated. Earthquakes at this depth of focus typically occur at oceanic-continental convergent boundaries, along Wadati–Benioff zones.[5]

Discovery

The evidence for deep-focus earthquakes was discovered in 1922 by H.H. Turner of Oxford, England. Previously, all earthquakes were considered to have shallow focal depths. The existence of deep-focus earthquakes was confirmed in 1931 from studies of the seismograms of several earthquakes, which in turn led to the construction of travel-time curves for intermediate and deep earthquakes.[6]

Fixed depth

When seismic data is too scarce to calculate a focal depth, a "fixed depth" is assigned. For example, many earthquakes occurring in oceans are assigned fixed depth because of limited local seismic records.[7] The United States Geological Survey presently determines to be the fixed depth for most shallow earthquakes as their actual focal depth is usually close to that value. Many earthquakes in their catalogue are assigned depth. The previous fixed depth used by the agency was .[8]

See also

Notes and References

  1. Spence, William, Stuart A. Sipkin, and George L. Choy (1989). "Measuring the Size of an Earthquake." Earthquake Information Bulletin (USGS). 21 (1), 58–63.
  2. Web site: National Earthquake Information Center. [ftp://hazards.cr.usgs.gov/maps/sigeqs/20050926/20050926.pdf M7.5 Northern Peru Earthquake of 26 September 2005]. 17 October 2005. 2008-08-01.
  3. Web site: USGS. [ftp://hazards.cr.usgs.gov/maps/sigeqs/20050926/20050926.pdf M7.5 Northern Peru Earthquake of 26 September 2005]. 2008-08-01.
  4. Greene II. H. W.. Burnley. P. C.. A new self-organizing mechanism for deep-focus earthquakes. Nature. 341. 6244. 733–737. October 26, 1989. 10.1038/341733a0. 1989Natur.341..733G. 4287597 .
  5. Marius Vassiliou, Bradford Hager, and Arthur Raefsky (1984): "The Distribution of Earthquakes with Depth and Stresses in Subducting Slabs", Journal of Geodynamics 1, 11–28.
  6. Spence, William, Stuart A. Sipkin, and George L. Choy (1989). Earthquake Information Bulletin (USGS). 21 (1), 58–63.
  7. Hongjian . Fang . Abercrombie . Rachel E. . A new method to determine the depth of earthquakes on oceanic transform faults using teleseismic arrays: application to the Chain transform, equatorial Atlantic . AGU Fall Meeting 2022, held in Chicago, IL, 12-16, id. T44A-04 . December 2022 .
  8. Web site: Why do so many earthquakes occur at a depth of 10km? . United States Geological Survey . 7 May 2024.