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.[1] 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 (also known as an intensity measure) for earthquake engineering, The design basis earthquake ground motion (DBEGM)[2] is often defined in terms of PGA.
Unlike the Richter and moment magnitude scales, it is not a measure of the total energy (magnitude, or size) of an earthquake, but rather of how much the earth shakes at a given geographic point. The Mercalli intensity scale uses personal reports and observations to measure earthquake intensity but PGA is measured by instruments, such as accelerographs. It can be correlated to macroseismic intensities on the Mercalli scale[3] but these correlations are associated with large uncertainty.[4][5]
The peak horizontal acceleration (PHA) is the most commonly used type of ground acceleration in engineering applications. It is often used within earthquake engineering (including seismic building codes) and it is commonly plotted on seismic hazard maps.[6] In an earthquake, damage to buildings and infrastructure is related more closely to ground motion, of which PGA is a measure, rather than the magnitude of the earthquake itself. For moderate earthquakes, PGA is a reasonably good determinant of damage; in severe earthquakes, damage is more often correlated with peak ground velocity.[3]
Geophysics
editEarthquake energy is dispersed in waves from the hypocentre, causing ground movement omnidirectionally but typically modelled horizontally (in two directions) and vertically. PGA records the acceleration (rate of change of speed) of these movements, while peak ground velocity is the greatest speed (rate of movement) reached by the ground, and peak displacement is the distance moved.[7][8] These values vary in different earthquakes, and in differing sites within one earthquake event, depending on a number of factors. These include the length of the fault, magnitude, the depth of the quake, the distance from the epicentre, the duration (length of the shake cycle), and the geology of the ground (subsurface). Shallow-focused earthquakes generate stronger shaking (acceleration) than intermediate and deep quakes, since the energy is released closer to the surface.[9]
Peak ground acceleration can be expressed in fractions of g (the standard acceleration due to Earth's gravity, equivalent to g-force) as either a decimal or percentage; in m/s2 (1 g = 9.81 m/s2);[7] or in multiples of Gal, where 1 Gal is equal to 0.01 m/s2 (1 g = 981 Gal).
The ground type can significantly influence ground acceleration, so PGA values can display extreme variability over distances of a few kilometers, particularly with moderate to large earthquakes.[10] The varying PGA results from an earthquake can be displayed on a shake map.[11] Due to the complex conditions affecting PGA, earthquakes of similar magnitude can offer disparate results, with many moderate magnitude earthquakes generating significantly larger PGA values than larger magnitude quakes.
During an earthquake, ground acceleration is measured in three directions: vertically (V or UD, for up-down) and two perpendicular horizontal directions (H1 and H2), often north–south (NS) and east–west (EW). The peak acceleration in each of these directions is recorded, with the highest individual value often reported. Alternatively, a combined value for a given station can be noted. The peak horizontal ground acceleration (PHA or PHGA) can be reached by selecting the higher individual recording, taking the mean of the two values, or calculating a vector sum of the two components. A three-component value can also be reached, by taking the vertical component into consideration also.
In seismic engineering, the effective peak acceleration (EPA, the maximum ground acceleration to which a building responds) is often used, which tends to be ⅔ – ¾ the PGA.[citation needed]
Seismic risk and engineering
editStudy of geographic areas combined with an assessment of historical earthquakes allows geologists to determine seismic risk and to create seismic hazard maps, which show the likely PGA values to be experienced in a region during an earthquake, with a probability of exceedance (PE). Seismic engineers and government planning departments use these values to determine the appropriate earthquake loading for buildings in each zone, with key identified structures (such as hospitals, bridges, power plants) needing to survive the maximum considered earthquake (MCE).
Damage to buildings is related to both peak ground velocity (PGV) and the duration of the earthquake – the longer high-level shaking persists, the greater the likelihood of damage.
Comparison of instrumental and felt intensity
editPeak ground acceleration provides a measurement of instrumental intensity, that is, ground shaking recorded by seismic instruments. Other intensity scales measure felt intensity, based on eyewitness reports, felt shaking, and observed damage. There is correlation between these scales, but not always absolute agreement since experiences and damage can be affected by many other factors, including the quality of earthquake engineering.
Generally speaking,
- 0.001 g (0.01 m/s2) – perceptible by people
- 0.02 g (0.2 m/s2) – people lose their balance
- 0.50 g (5 m/s2) – very high; well-designed buildings can survive if the duration is short.[8]
Correlation with the Mercalli scale
editThe United States Geological Survey developed an Instrumental Intensity scale, which maps peak ground acceleration and peak ground velocity on an intensity scale similar to the felt Mercalli scale. These values are used to create shake maps by seismologists around the world.[3]
Instrumental Intensity |
Acceleration (g) |
Velocity (cm/s) |
Perceived shaking | Potential damage |
---|---|---|---|---|
I | < 0.000464 | < 0.0215 | Not felt | None |
II–III | 0.000464 – 0.00297 | 0.135 – 1.41 | Weak | None |
IV | 0.00297 – 0.0276 | 1.41 – 4.65 | Light | None |
V | 0.0276 – 0.115 | 4.65 – 9.64 | Moderate | Very light |
VI | 0.115 – 0.215 | 9.64 – 20 | Strong | Light |
VII | 0.215 – 0.401 | 20 – 41.4 | Very strong | Moderate |
VIII | 0.401 – 0.747 | 41.4 – 85.8 | Severe | Moderate to heavy |
IX | 0.747 – 1.39 | 85.8 – 178 | Violent | Heavy |
X+ | > 1.39 | > 178 | Extreme | Very heavy |
Other intensity scales
editIn the 7-class Japan Meteorological Agency seismic intensity scale, the highest intensity, Shindo 7, covers accelerations greater than 4 m/s2 (0.41 g).
PGA hazard risks worldwide
editIn India, areas with expected PGA values higher than 0.36 g are classed as "Zone 5", or "Very High Damage Risk Zone".
Notable earthquakes
editSee also
editReferences
edit- ^ Douglas, J (2003-04-01). "Earthquake ground motion estimation using strong-motion records: a review of equations for the estimation of peak ground acceleration and response spectral ordinates" (PDF). Earth-Science Reviews. 61 (1–2): 43–104. Bibcode:2003ESRv...61...43D. doi:10.1016/S0012-8252(02)00112-5.
- ^ Nuclear Power Plants and Earthquakes Archived 2009-07-22 at the Wayback Machine. Retrieved 8 April 2011.
- ^ a b c "ShakeMap Scientific Background. Rapid Instrumental Intensity Maps". Earthquake Hazards Program. United States Geological Survey. Archived from the original on 23 June 2011. Retrieved 22 March 2011.
- ^ Cua, G.; et al. (2010). "Best Practices" for Using Macroseismic Intensity and Ground Motion Intensity Conversion Equations for Hazard and Loss Models in GEM1 (PDF). Global Earthquake Model. Archived from the original (PDF) on 27 December 2015. Retrieved 11 November 2015.
- ^ See also: Seismic magnitude scales
- ^ European Facilities for Earthquake Hazard & Risk (2013). "The 2013 European Seismic Hazard Model (ESHM13)". EFEHR. Archived from the original on 27 December 2015. Retrieved 11 November 2015.
- ^ a b "Explanation of Parameters". Geologic Hazards Science Center. United States Geological Survey. Archived from the original on 21 July 2011. Retrieved 22 March 2011.
- ^ a b Lorant, Gabor (17 June 2010). "Seismic Design Principles". Whole Building Design Guide. National Institute of Building Sciences. Retrieved 15 March 2011.
- ^ "Magnitude 6.6 – Near the west coast of Honshu, Japan". Earthquake summary. United States Geological Survey. 16 July 2001. Archived from the original on 14 March 2011. Retrieved 15 March 2011.
- ^ "ShakeMap scientific background. Peak acceleration maps". Earthquake Hazards Program. United States Geological Survey. Archived from the original on 23 June 2011. Retrieved 22 March 2011.
- ^ "ShakeMap Scientific Background". Earthquake Hazards Program. United States Geological Survey. Archived from the original on 23 June 2011. Retrieved 22 March 2011.
- ^ Goto, Hiroyuki; Kaneko, Yoshihiro; Young, John; Avery, Hamish; Damiano, Len (4 February 2019). "Extreme Accelerations During Earthquakes Caused by Elastic Flapping Effect". Scientific Reports. 9 (1): 1117. Bibcode:2019NatSR...9.1117G. doi:10.1038/s41598-018-37716-y. PMC 6361895. PMID 30718810.
- ^ "M 9.5 – 1960 Great Chilean Earthquake (Valdivia Earthquake)". United States Geological Survey. Retrieved 21 September 2023.
- ^ Schäfer, Andreas, et al. Center for Disaster Management and Risk Reduction Technology CEDIM Forensic Disaster Analysis Group (FDA). 2024, www.cedim.kit.edu/download/FDA_EQ_Japan2024.pdf, https://doi.org/10.5445/IR/1000166937. Retrieved 3 Apr. 2024.
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- ^ "2011 Off the Pacific Coast of Tohoku earthquake, Strong Ground Motion" (PDF). National Research Institute for Earth Science and Disaster Prevention. Archived from the original (PDF) on 24 March 2011. Retrieved 18 March 2011.
- ^ "M 9.1 – 2011 Great Tohoku Earthquake, Japan – Origin". United States Geological Survey. Retrieved 10 November 2021.
- ^ "Archived copy of USGS Magnitude 7 and Greater Earthquakes in 2011". Archived from the original on 13 April 2016. Retrieved 8 September 2017.
- ^ "平成23年(2011年)東北地方太平洋沖地震(東日本大震災)について(第162報)(令和4年3月8日)" [Press release no. 162 of the 2011 Tohuku earthquake] (PDF). 総務省消防庁災害対策本部 [Fire and Disaster Management Agency]. Archived from the original (PDF) on 2022-08-27. Retrieved 2022-09-23. Page 31 of the PDF file.
- ^ Masumi Yamada; et al. (July–August 2010). "Spatially Dense Velocity Structure Exploration in the Source Region of the Iwate-Miyagi Nairiku Earthquake". Seismological Research Letters v. 81; no. 4. Seismological Society of America. pp. 597–604. Retrieved 21 March 2011.
- ^ "【速報】揺れの最大加速度、東日本大震災に匹敵". 47news. 2 January 2024. Retrieved 4 January 2024.
- ^ "M 7.7 – 21 km S of Puli, Taiwan". United States Geological Survey. Retrieved 10 November 2021.
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- ^ "M 6.7 – 1 km NNW of Reseda, CA". United States Geological Survey. Retrieved 10 November 2021.
- ^ "M 7.8 – Pazarcik earthquake, Kahramanmaras earthquake sequence". Archived from the original on 2023-03-02. Retrieved 2023-04-07.
- ^ "Feb 22 2011 – Christchurch badly damaged by magnitude 6.3 earthquake". GeoNet. 23 February 2011. Archived from the original on 4 March 2011. Retrieved 24 February 2011.
- ^ "PGA intensity map". GeoNet. Archived from the original on 31 May 2012. Retrieved 24 February 2011.
- ^ "New Zealand Earthquake Report – Feb 22 2011 at 12:51 pm (NZDT)". GeoNet. 22 February 2011. Archived from the original on 25 February 2011. Retrieved 24 February 2011.
- ^ Carter, Hamish (24 February 2011). "Technically it's just an aftershock". The New Zealand Herald. Retrieved 24 February 2011.
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- ^ Cloud & Hudson 1975, pp. 278, 287
- ^ Katsuhiko, Ishibashi (11 August 2001). "Why Worry? Japan's Nuclear Plants at Grave Risk From Quake Damage". Japan Focus. Asia Pacific Journal. Retrieved 15 March 2011.
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Bibliography
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