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- Here is IRIS’ page for this earthquake<\/a>.<\/li>\n<\/ul>\n
Below is my interpretive poster for this earthquake<\/font><\/h2>\n
I plot the seismicity from the past month, with color representing depth and diameter representing magnitude (see legend). I include earthquake epicenters from 1918-2018 with magnitudes M \u2265 6.5 (and down to M \u2265 5.5 in a second poster).
\nI plot the USGS fault plane solutions (moment tensors in blue and focal mechanisms in orange) for the M 7.3 earthquakes, in addition to some relevant historic earthquakes.<\/p>\nUPDATE 2018.01.15<\/h3>\n
- 2018.01.15 M 7.1 Peru<\/a> Update #1<\/li>\n
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- I placed a moment tensor \/ focal mechanism legend on the poster. There is more material from the USGS web sites about moment tensors<\/a> and focal mechanisms<\/a> (the beach ball symbols). Both moment tensors and focal mechanisms are solutions to seismologic data that reveal two possible interpretations for fault orientation and sense of motion. One must use other information, like the regional tectonics, to interpret which of the two possibilities is more likely. <\/li>\n
- I also include the shaking intensity contours on the map. These use the Modified Mercalli Intensity Scale (MMI; see the legend on the map). This is based upon a computer model estimate of ground motions, different from the “Did You Feel It?” estimate of ground motions that is actually based on real observations. The MMI is a qualitative measure of shaking intensity. More on the MMI scale can be found here<\/a> and here<\/a>. This is based upon a computer model estimate of ground motions, different from the “Did You Feel It?” estimate of ground motions that is actually based on real observations.<\/li>\n
- I include the slab contours plotted (Hayes et al., 2012<\/a>), which are contours that represent the depth to the subduction zone fault. These are mostly based upon seismicity. The depths of the earthquakes have considerable error and do not all occur along the subduction zone faults, so these slab contours are simply the best estimate for the location of the fault.<\/li>\n<\/ul>\n
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- I include (faintly) the MMI contours from most of the larger magnitude earthquakes for which there are data available. As mentioned above, these are estimates based upon numerical models using empirical relations between earthquakes and their shaking intensity. These MMI estimates are controlled by a variety of things, principally magnitude and distance to the fault. Some estimates are made using rectangular shaped fault sources (e.g. 2001 M 8.4), some from point source distances (e.g. 1966 M 8.1).<\/li>\n
- I outline the MMI VII contour because (1) this is the largest MMI contour for the M 7.1 earthquake and (2) this is the “very strong” shaking intensity that can cause moderate damage to buildings. These outlines are in dashed white and are labeled in yellow for the causative earthquake magnitude. The M 7.1 MMI VII contour is from a point source, so would probably be more rectangular in reality (though the earthquake is deeper).<\/li>\n<\/ul>\n
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I include some inset figures.<\/strong><\/h3>\n<\/li>\n
- In the upper right corner is a section of the map from Rhea et al. (2010), which is a USGS map documenting the seismicity of the earth in this region. The cross section B-B’ is shown to the left. The cross section plots the earthquake depths along the profile shown on the map. The B-B’ profile crosses the subduction zone very close to where this earthquake happened. I place a blue star in the general location of today’s M 7.1 earthquake.<\/li>\n
- In the lower right corner is a map from Chlieh et al. (2011) that shows some historic earthquake slip patches. The colors represent the amount of slip on the earthquake fault. I place a blue star in the general location of today’s M 7.1 earthquake. Note how this M 7.1 earthquake is at the boundary of the 2001 M 8.4 and 1996 M 7.7 earthquakes.<\/li>\n
- In the upper right corner is a figure that addresses, from left to right:\n
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- Historic (including pre-instrumental) earthquakes, their along-strike distances<\/li>\n
- Slip patches for instrumental earthquakes; I place a blue star in the general location of today’s M 7.1 earthquake.<\/li>\n
- Seismic moment for instrumental earthquakes; Seismic moment is the amount of energy released during an earthquake. The 2007, 1996, and 2001 earthquakes are part of their analyses and contain more details about the heterogeneous nature of earthquake faults.<\/li>\n<\/ol>\n
- In the lower left corner is another figure from Chlieh et a. (2011) that provides lots of details from their analyses. <\/li>\n
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- On the left is the a plot of the Seismic Moment as before, with the addition of Moment Deficit. Moment deficit is an estimate of the amount of energy stored in the subduction zone as imparted by plate convergence. Assumptions include (at least) plate motion rates and spatial variation in the amount the fault is seismogenically locked\/coupled, etc. Today’s earthquake happened nearby a 1913 M 7.8 earthquake in a region of low moment deficit.<\/li>\n
- On the right is a plot showing the historic earthquakes again, but with the addition of the coupling ratio. The coupling ratio is the proportion of 100% of the plate motion that is contributing to the strain on the fault. A coupling ratio of 1 (100%) means that 100% of the plate motion is being accumulated as stress on the fault. A ratio of 0 (0%) means that the fault is aseismic (it is slipping all the time). I place a blue star in the general location of today’s M 7.1 earthquake. The 1942, 1996, and today’s M 7.1 earthquakes are along the southern boundary of the NR and in a region of low coupling. <\/li>\n<\/ol>\n<\/li>\n<\/ul>\n
\n![\"\"](\"http:\/\/earthjay.com\/earthquakes\/20180114_peru\/20180114_peru_interpretation_65.jpg\")
<\/a>
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\n![\"\"](\"http:\/\/earthjay.com\/earthquakes\/20180114_peru\/20180114_peru_interpretation_55.jpg\")
<\/a><\/p>\nUSGS Earthquake Pages<\/font><\/strong><\/h2>\n
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- M 7.1 – 40km SSW of Acari, Peru
\n2018-01-14 09:18:45 UTC 15.776\u00b0S 74.744\u00b0W 36.3 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/us2000cjfy#executive<\/a><\/li>\n- M 8.2 – near the coast of central Peru
\n1940-05-24 16:33:59 UTC 11.094\u00b0S 77.487\u00b0W 45.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/iscgem901374#executive <\/a><\/li>\n- M 8.1 – near the coast of central Peru
\n1966-10-17 21:42:00 UTC 10.665\u00b0S 78.228\u00b0W 40.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/iscgem842581#executive<\/a><\/li>\n- M 7.6 – near the coast of central Peru
\n1974-10-03 14:21:29 UTC 12.265\u00b0S 77.795\u00b0W 13.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usp0000888#executive<\/a><\/li>\n- M 7.2 – near the coast of central Peru
\n1974-11-09 12:59:49 UTC 12.500\u00b0S 77.786\u00b0W 6.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usp00008qy#executive<\/a><\/li>\n- M 7.7 – near the coast of central Peru
\n1996-11-12 16:59:44 UTC 14.993\u00b0S 75.675\u00b0W 33.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usp0007swp#executive<\/a><\/li>\n- M 8.4 – near the coast of southern Peru
\n2001-06-23 20:33:14 UTC 16.265\u00b0S 73.641\u00b0W 33.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/official20010623203314130_33#executive<\/a><\/li>\n- M 7.6 – near the coast of southern Peru
\n2001-07-07 09:38:43 UTC 17.543\u00b0S 72.077\u00b0W 33.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usp000aj40#executive<\/a><\/li>\n- M 8.0 – near the coast of central Peru
\n2007-08-15 23:40:57 UTC 13.386\u00b0S 76.603\u00b0W 39.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usp000fjta#executive<\/a><\/li>\n- M 7.1 – 46km SSE of Acari, Peru
\n2013-09-25 16:42:43 UTC 15.839\u00b0S 74.511\u00b0W 40.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usb000jzma#executive<\/a><\/li>\n- M 8.2 – 94km NW of Iquique, Chile
\n2014-04-01 23:46:47 UTC 19.610\u00b0S 70.769\u00b0W 25.0 km depth
\nhttps:\/\/earthquake.usgs.gov\/earthquakes\/eventpage\/usc000nzvd#executive<\/a><\/li>\n- \n
- Here is an animation from IRIS that reviews the tectonics of the Peru-Chile subduction zone. For the animation, first is a screen shot and below that is the embedded video. This animation is from IRIS<\/a>. Written and directed by Robert F. Butler, University of Portland. Animation and Graphics: Jenda Johnson, geologist. Consultant: Susan Beck, University or Arizona. Narration: Elayne Shapiro, University of Portland.<\/li>\n
\n![\"\"](\"http:\/\/earthjay.com\/earthquakes\/20151124_peru\/A_007_PeruChile.JPG\")
<\/a><\/p>\n- Here is a download link<\/a> for the embedded video below (34 MB mp4)<\/li>\n<\/ul>\n
\n - Here is a download link<\/a> for the embedded video below (34 MB mp4)<\/li>\n<\/ul>\n
Some Relevant Discussion and Figures<\/font><\/strong><\/h2>\n
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- M 8.2 – near the coast of central Peru
These are from this current sequence<\/strong><\/h3>\n
- M 7.1 – 40km SSW of Acari, Peru
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- I also include the shaking intensity contours on the map. These use the Modified Mercalli Intensity Scale (MMI; see the legend on the map). This is based upon a computer model estimate of ground motions, different from the “Did You Feel It?” estimate of ground motions that is actually based on real observations. The MMI is a qualitative measure of shaking intensity. More on the MMI scale can be found here<\/a> and here<\/a>. This is based upon a computer model estimate of ground motions, different from the “Did You Feel It?” estimate of ground motions that is actually based on real observations.<\/li>\n
- 2018.01.15 M 7.1 Peru<\/a> Update #1<\/li>\n