Acapulco earthquake struck the edge of a seismic gap

On September 7, 2021, a strong earthquake struck near Acapulco, Mexico. The earthquake may have increased the likelihood of a larger magnitude earthquake within the Guerrero Seismic Gap.
 

By Hector Gonzalez-Huizar, Centro de Investigación Científica y de Educación Superior de Ensenada, Baja California (CICESE), Xyoli Pérez-Campos, Instituto de Geofísica, Universidad Nacional Autónoma de México (UNAM), and Aaron A. Velasco, University of Texas at El Paso (UTEP)
 

Citation: Gonzalez-Huizar, H., Pérez-Campos, X., Velasco, A.A., 2021, Acapulco earthquake struck the edge of a seismic gap, Temblor, http://doi.org/10.32858/temblor.218
 

Acapulco de Juárez, Guerrero, México. Credit: Herminio González Huizar
Acapulco de Juárez, Guerrero, México. Credit: Herminio González Huizar

 

On September 7, 2021, a magnitude-7.1 earthquake struck near the coast of Guerrero, Mexico. The earthquake was widely felt — even in Mexico City, more than 220 miles (350 kilometers) away — and caused damage to buildings in the nearby tourist city of Acapulco.

The earthquake struck very close to an area that had not seen a large earthquake in the past century, leading scientists to wonder if it could trigger an earthquake that would fill a so-called “gap” along Mexico’s otherwise seismically active Pacific coast.

In this region, the Cocos tectonic plate subducts underneath the North American plate. This tectonic boundary — one of the most seismically active in the world — has a long history of large, damaging earthquakes. In 1787, a magnitude-8.4–8.6 earthquake, the biggest in Mexico’s history, occurred in the region (Suárez and Albini, 2009). In 1985, the country’s deadliest earthquake, a magnitude-8.0, struck along the boundary, causing about 10,000 deaths, most of which occurred in Mexico City, far from the epicenter.

Other past, damaging earthquakes in Acapulco and nearby towns include a magnitude-8.2 in 1907, a magnitude-7.8 in 1909, a magnitude-7.8 in 1957, and two earthquakes of magnitude-7.1 and -7.2 in 1962, which occurred just eight days apart. Given the poor precision in the estimated location of these historic earthquakes, the September 2021 earthquake may have occurred in the same rupture area.
 

Location uncertainty

September’s earthquake struck roughly seven miles (11 kilometers) southwest of Acapulco, according to the Servicio Sismólogico Nacional (SSN), Mexico’s earthquake monitoring agency. The United States Geological Survey (USGS) and other global agencies estimate it struck between 10 and 15 miles (17 and 23 kilometers) to the northeast of this location.

However, agencies that use global seismic networks to locate earthquakes in the Mexican subduction zone, such as the USGS, systematically mislocate such events by roughly 16 miles (26 kilometers) to the northeast (Singh and Lermo, 1985; Hjörleifsdóttir, et al, 2016). The errors are attributed to lateral variations in the mantle structure, which affect the velocity of the seismic waves detected by seismometers. These errors become exaggerated when stations far from the epicenter are used (Hjörleifsdóttir, et al, 2016).
 

The Guerrero Seismic Gap

The epicenter of the recent Acapulco earthquake lies at the eastern edge of the Guerrero Seismic Gap, a zone of apparent seismic quiescence embedded in this highly active seismic region.

The last large earthquake — greater than or equal to magnitude-7.0 — in the Guerrero Gap occurred more than a century ago, in 1911, whereas for the rest of the tectonic plate boundary, large earthquakes occur approximately every 30 to 60 years (Nishenko and Singh, 1987). Moreover, ruptures from previous, proximal events of magnitude-8.0 and larger did not propagate into the gap.

Seismic gaps can indicate that stress, usually released during earthquakes, is building up along a locked plate boundary. In the case of the Guerrero Gap, some researchers estimate enough stress has accumulated to cause a magnitude-8.0 or larger earthquake (Singh and Mortera, 1991) and a major tsunami. Such a large event could cause significant damage to nearby coastal cities such as Acapulco, as well as to Mexico City, where seismic waves are amplified by the underlying soft sediment (an ancient lakebed).

Alternatively, recent studies suggest that within this gap, the plate boundary is sliding freely. In this case, stress imparted by the tectonic plates sliding past one another is nearly continuously released. If true, the probability of a big earthquake occurring is significantly lower (Husker et al., 2018; Plata-Martinez et al., 2021). The latter hypothesis stems from studies that suggest the Guerrero Gap’s deep-seated zone where slow slip events occur — one of the largest in the world — could reach into the shallower depths where large earthquakes are usually generated. (Kostologlov et al., 2003).
 

(Top) Map showing the epicenters (grey circles) of large earthquakes since 1900 (SSN, 2021). The red circle and cross mark the epicenter of the September 2021 Acapulco earthquake reported by the SSN and USGS, respectively. The earthquake’s focal mechanism (beachball) is presented. Blue arrows point to the epicenters of the deadliest and the largest earthquakes in Mexican history. (Bottom) Map showing the year of occurrence of earthquakes. Open triangles represent the seismic stations from the SSN. Yellow and red areas represent areas where slow slip events and tectonic tremors occur. Dashed circles represent the epicenters of the latest large earthquakes located inside the gap. The green arrow points to the Acapulco earthquake.
(Top) Map showing the epicenters (grey circles) of large earthquakes since 1900 (SSN, 2021). The red circle and cross mark the epicenter of the September 2021 Acapulco earthquake reported by the SSN and USGS, respectively. The earthquake’s focal mechanism (beachball) is presented. Blue arrows point to the epicenters of the deadliest and the largest earthquakes in Mexican history. (Bottom) Map showing the year of occurrence of earthquakes. Open triangles represent the seismic stations from the SSN. Yellow and red areas represent areas where slow slip events and tectonic tremors occur. Dashed circles represent the epicenters of the latest large earthquakes located inside the gap. The green arrow points to the Acapulco earthquake.

 

Triggering by the Acapulco Earthquake

An earthquake can change the physical conditions of nearby faults, potentially triggering more earthquakes (termed static triggering). A parameter known as “Coulomb stress change” describes where earthquakes are more likely to be triggered. In general, stress changes greater than 0.1 bar (force per unit area) suggest a high probability of triggering (Hill, 2008).

We modeled the Coulomb stress change (Toda et al., 2011) caused by the Acapulco earthquake, and discovered that a large area of the Guerrero Seismic Gap was brought closer to triggering. Stress change values above 0.1 bar could be reached as far as the epicenter of 1911 earthquake.
 

Static Coulomb stress change caused by the Acapulco earthquake. Hot (red) colors indicate areas where future earthquakes are more likely to be triggered. The area surrounded by the dashed red line experiences a value greater than 0.1 bar. Green and orange circles are earthquakes that occurred within 10 days after the Acapulco earthquake (obtained from the Servicio Sismológico Nacional). The dashed open circle represents the epicenter of the latest (1911) large earthquake inside the gap.
Static Coulomb stress change caused by the Acapulco earthquake. Hot (red) colors indicate areas where future earthquakes are more likely to be triggered. The area surrounded by the dashed red line experiences a value greater than 0.1 bar. Green and orange circles are earthquakes that occurred within 10 days after the Acapulco earthquake (obtained from the Servicio Sismológico Nacional). The dashed open circle represents the epicenter of the latest (1911) large earthquake inside the gap.

 

Earthquakes can be triggered in other ways. During an earthquake, seismic waves radiate outward from the ruptured area. Ground deformation related to the passing of seismic waves can also generate Coulomb stress change values large enough to trigger earthquakes — a phenomenon known as “dynamic triggering” (Gonzalez-Huizar et al., 2012). In some cases, the triggering occurs during the passing of the seismic waves, but in other cases, there is a delay between the waves passing and the triggering of the earthquakes (Castro et al., 2015, Gonzalez-Huizar and Toda, 2021). It is not clear, however, what controls this delay time. It is possible that the passing waves initiate a small slow slip event or cause permanent damage on the faults. Such events could gradually trigger earthquakes (Parsons 2005; Shelly et al., 2011).

We modeled the Coulomb stress change caused by the seismic waves from the Acapulco earthquake passing through the Guerrero Gap. Values larger than 0.1 bar were generated inside the gap (lower panel in the following figure), which might have implications in the occurrence of future events along the gap.

Fewer aftershocks following the Acapulco earthquake occurred inside the Guerrero Seismic Gap than to the opposite side of the epicenter, outside the gap. This suggests that, like large earthquakes, smaller magnitude aftershocks are not readily produced within the Guerrero Gap, indicating that this area has stored relatively little tectonic stress. This observation might support the hypothesis that the Guerrero seismic gap is undergoing nearly continuous slip. However, our modeling shows that the Acapulco earthquake and its seismic waves increased stress within the gap — enough to trigger a future large magnitude earthquake.

Our results are preliminary, and as the scientific community obtains better models for the geometry of the rupture of the Acapulco earthquake, the location of its aftershocks, and the physical characteristics of the gap, our results can be refined.
 

In all panels, the horizontal axis represents the distance from point A to point A’ in the map in the previous figure. The red circle represents the focus of the Acapulco earthquake and the semitransparent area the Guerrero Seismic Gap. (a) Epicenters of past large magnitude earthquakes. (b) Time evolution of the aftershocks of the Acapulco earthquake. (c) Magnitude of aftershocks. (d) Histogram of aftershocks. (e) Static Coulomb stress change caused by the Acapulco earthquake. (f) Dynamic Coulomb stress change caused by the propagation of the seismic waves from the Acapulco earthquake, where arrows represent the direction of propagation of the waves.
In all panels, the horizontal axis represents the distance from point A to point A’ in the map in the previous figure. The red circle represents the focus of the Acapulco earthquake and the semitransparent area the Guerrero Seismic Gap. (a) Epicenters of past large magnitude earthquakes. (b) Time evolution of the aftershocks of the Acapulco earthquake. (c) Magnitude of aftershocks. (d) Histogram of aftershocks. (e) Static Coulomb stress change caused by the Acapulco earthquake. (f) Dynamic Coulomb stress change caused by the propagation of the seismic waves from the Acapulco earthquake, where arrows represent the direction of propagation of the waves.

 

References

Castro, R.R., H. Gonzalez‐Huizar, F. Zúñiga, V.M. Wong, and A.A. Velasco (2015). Delayed dynamic triggered seismicity in northern Baja California, México caused by large and remote earthquakes. Bull. Seismol. Soc. Am., 105(4), 1825-1835. doi:10.1785/0120140310.

Hill, D. P. (2008). Dynamic stresses, Coulomb failure, and remote triggering. Bull. Seismol. Soc. Am., 98(1), 66-92. doi:10.1785/0120070049.

Hjörleifsdóttir, V., S.K. Singh and A. Husker (2016), Differences in epicentral locations of Mexican earthquakes between local and global catalogs: An update. Geofísica Internacional, 51, 1, 79-93.

Husker, A., L. Ferrari, C. Arango-Galván, F. Corbo-Camargo, and J.A.A. Arzate-Flores (2018). Geologic recipe for transient slip within the seismogenic zone: insight from the Guerrero seismic gap, Mexico. Geol. Soc. Am. 46, 35–38.

Gonzalez‐Huizar, H., and A.A. Velasco (2011). Dynamic triggering: Stress modeling and a case study. Journal of Geophysical Research: Solid Earth, 116(B2). doi:10.1029/2009JB007000.

Gonzalez-Huizar, H., A.A. Velasco, Z. Peng, and R.R. Castro (2012) Remote triggered seismicity caused by the 2011 M9.0 Tohoku-Oki, Japan earthquake. Geophys. Res. Lett. 39, L10302.

Gonzalez-Huizar, H., and S. Toda (2021). New Zealand sees exotic earthquake sequence, Temblor, http://doi.org/10.32858/temblor.160.

Kostoglodov, V. et al. (2003), A large silent earthquake in the Guerrero seismic gap, Mexico. Geophys. Res. Lett. 30, 1807.

Nishenko, S.P. and S.K. Singh (1987) Conditional probabilities for the recurrence of large and great interplate earthquakes along the Mexican subduction zone: Bull. Seismol. Soc. Am., v. 77, p. 2095–2114, 10.1029/JB090iB05p03589.

Parsons, T. (2005), A hypothesis for delayed dynamic earthquake triggering. Geophysical Research Letters, 32(4). doi:10.1029/2004GL021811.

Singh S.K. and J. Lermo (1985), Mislocations of Mexican earthquakes as reported in international bulletins, Geofísica Internacional, 24, 2, 333-351.

Plata-Martinez, R. et al. (2021) Shallow slow earthquakes to decipher future catastrophic earthquakes in the Guerrero seismic gap, Nature Communications, https://doi.org/10.1038/s41467-021-24210-9.

Shelly, D. R., Z. Peng, D.P. Hill and C. Aiken (2011). Triggered creep as a possible mechanism for delayed dynamic triggering of tremor and earthquakes. Nature Geoscience, 4(6), 384-388. https://doi.org/10.1038/ngeo1141.

Toda, S., R.S. Stein, V. Sevilgen, and J. Lin (2011), Coulomb 3.3 Graphic-rich deformation and stress-change software for earthquake, tectonic, and volcano research and teaching—user guide: U.S. Geological Survey Open-File Report 2011–1060, 63 p., available at https://pubs.usgs.gov/of/2011/1060/.

Singh, S., and F. Mortera (1991) Source time functions of large Mexican subduction earthquakes, morphology of the Benioff zone, age of the plate, and their tectonic implications. J. Geophys. Res. 96, 21,487–21,502.

SSN (2021) Universidad Nacional Autónoma de México, Instituto de Geofísica, Servicio Sismológico Nacional, México, http://www.ssn.unam.mx.

Suárez, G. and P. Albini (2009) Evidence for great tsunamigenic earthquakes (M 8.6) along the Mexican subduction zone, Bull. Seismol. Soc. Am. 99, no. 2A, 892–896, doi: 10.1785/0120080201.
 

Further Reading

Cruz-Atienza, V. M. et al. A seismogeodetic amphibious network in the Guerrero seismic gap Mexico. Seismol. Res. Lett. 89, 1435–1449 (2018).

Gonzalez-Huizar, H. (2019) La Olimpiada XXIV de Ciencias de la Tierra: Los Grandes Terremotos de México, GEOS, 39 (1).

Husker, A., W.B. Frank, G. Gonzalez, L. Avila, V. Kostoglodov and E. Kazachkina (2019) Characteristic Tectonic Tremor Activity Observed Over Multiple Slow Slip Cycles in the Mexican Subduction Zone. Journal of Geophysical Research: Solid Earth, 124(1), 599–608. https://doi.org/10.1029/2018JB016517.