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Luzon, Philippines, sees sixth strong earthquake in five months

Is this an unusually productive aftershock sequence, or could these quakes prove to be foreshocks of a larger event that has yet to strike?
 

By Mario Aurelio, Director of the University of the Philippines National Institute of Geological Sciences, Sandra Donna Catugas, Structural Geology and Tectonics Laboratory at the University of Philippines National Institute of Geological Sciences, John Agustin Escudero, Structural Geology and Tectonics Laboratory at the University of Philippines National Institute of Geological Sciences, Alfredo Mahar Francisco Lagmay, Executive Director, University of the Philippines Resilience Institute-Nationwide Operational Assessment of Hazards Center (@nababaha), Giovanni A. Tapang, Dean of the University of the Philippines-Diliman, College of Science
 

Citation: Aurelio, M., Catugas, S.D., Escudero, J. A., Lagmay, A.F.M. and Tapang, G., 2021, Luzon, Philippines, sees sixth strong earthquake in five months, Temblor, http://doi.org/10.32858/temblor.225
 

On December 13, 2021, at 5:12 p.m. local time, the Batangas region in southern Luzon, Philippines, was hit by the fifth earthquake with a magnitude greater than 5.0 since a magnitude-6.6 tremor on July 24, 2021 (Aurelio et al., 2021a; 2021b; 2021c). Prior to this, four earthquakes with magnitude-5.8 (July 24 and August 13), 5.7 (September 27) and 5.2 (October 7) struck within a radius of 20 miles (30 kilometers) of the first July 24 event. This recurrence interval — an average of more than one strong earthquake every month — is too short to be neglected. This is either an unusually vigorous aftershock sequence, or an event comparable to a seismic swarm.
 

Area of stress increase

Using the fault responsible for generating the magnitude-6.6 earthquake of July 24, as the source fault, Coulomb stress transfer modeling indicates that the magnitude-5.5 tremor of December 13 falls within the lobe of increased stress when used as the receiver fault (Fig. 1). The 65-mile (104-kilometer) depth of the December tremor also plots approximately along the same fault plane, but four miles (seven kilometers) shallower than the July 24 event. These observations suggest that the first earthquake likely triggered the second.
 

Figure 1. Seismotectonics of six moderate magnitude, thrust-mechanism earthquakes (shown by beachballs) occurring in the same region in Batangas, southern Luzon, Philippines, within a period of five months (July 24 to December 13, 2021). Result of Coulomb stress change modeling shown. July 24 magnitude-6.6 as source; December 13 magnitude-5.5 as receiver. References: Jarvis et al., 2008 for SRTM topography; Weatherall et al., 2020 for bathymetry; Toda et al., 2011 for Coulomb stress transfer modeling; PHIVOLCS for earthquake data. GMT (Wessel and Smith, 1995) was used to generate the map. See text for more discussion. Credit: Aurelio, Catugas, Escudero, Lagmay,Tapang

 

The same triggering mechanism can explain three of the other recent magnitude-5.0 and larger events when each is used as the receiver fault (Aurelio et al., 2021a; 2021b), except for the magnitude-5.7 quake of September 27, which occurred in a zone of decreased stress (Aurelio et al., 2021c).

However, when Coulomb stress transfer modeling considers an optimally-oriented receiver fault — assumed to be aligned with the stress field, thus promoting failure — all five earthquakes that succeeded the July 24 magnitude-6.6 earthquake fall within the lobe of increased stress at 65 miles (104 kilometers) depth (Fig. 2). The hypocenters — the locations on the fault where each earthquake nucleated — cluster within the calculated region of increased stress, which suggests triggering of all five quakes by the magnitude-6.6 July 24 event.
 

Figure 2. Seismotectonics of six moderate magnitude, thrust-mechanism earthquakes (shown by beachballs) occurring in the same region in Batangas, southern Luzon, Philippines, within a period of five months (July 24 to December 13, 2021). Result of Coulomb stress change modeling shown. July 24 magnitude-6.6 as source, with optimally-oriented fault as receiver. References: Jarvis et al., 2008 for SRTM topography; Weatherall et al., 2020 for bathymetry; Toda et al., 2011 for Coulomb stress transfer modeling; PHIVOLCS for earthquake data. GMT (Wessel and Smith, 1995) was used to generate the map. See text for more discussion. Credit: Aurelio, Catugas, Escudero, Lagmay,Tapang

 

Cause for concern?

Based on the data collected during the last decade (Aurelio et al., 2021b), an average of 2.5 events larger than magnitude-5.0 strike per year within 50 kilometers of the July 24 magnitude-6.6 event. The recent spate of moderate quakes — each separated by less than a month — far exceeds this average and suggests that this is an evolving sequence.

Could these six moderate magnitude earthquakes occurring over a short period of time indicate that stresses are being released rapidly? Or could these be lower-magnitude foreshocks of a larger event that has yet to strike? The latter is a possibility and should serve as a reminder to the 25 million inhabitants of Metro Manila and surrounding provinces that this region is vulnerable to a large earthquake. Preparedness and readiness are vital.
 

Low-cost seismology studies

The December 13 tremor was recorded by low-cost seismometers partly belonging to Public Seismic Network that is currently being established by the College of Science of the University of the Philippines-Diliman (UP Diliman) in Quezon City (Fig. 3). These low-cost seismometers, developed by Raspberry Shake, have been tried and tested both in the laboratory (Anthony et al., 2019) and in the field (Manconi et al., 2018; Winter et al., 2021; Holmgren, 2021).
 

Figure 3. Earthquake information generated by a Raspberry Shake station located nearest to the Public Seismic Network hub located inside the University of the Philippines-Diliman campus in Quezon City. The figure is a screenshot from the mobile phone app showing on the: upper panel – the date and time (local) of the seismic event, earthquake parameters (magnitude-5.5 and focal depth of 157 kilometers), station ID: R5160, map showing the locations of the Raspberry Shake seismic station and the epicenter and, station-to-epicenter distance in kilometers; middle panel – the waveform of the earthquake, clearly delineating the first P and S waves; lower panel – wave frequency distribution as a function of time. Credit: Aurelio, Catugas, Escudero, Lagmay, Tapang

 

The earthquake parameters for December’s quake, generated by the UP Diliman-based network, include a calculated magnitude of 5.5, which compares well with magnitudes calculated by established international seismological observatories such as the U.S. Geological Survey – National Earthquake Information Center (USGS-NEIC), GEOFON German Research Center for Geosciences (GEOFON-GFZ, Potsdam, Germany) and PHIVOLCS (Philippines). The low-cost, Raspberry Shake-derived earthquake depth of 98 miles (157 kilometers) is close to that computed by USGS-NEIC, but varies significantly from GEOFON-GFZ (69 miles/111 kilometers) and PHIVOLCS (64 miles/104 kilometers) estimates.

Currently, most of these low-cost seismometers are owned and operated by ordinary citizens on their private properties. Though the stations are still scarce, there are good indications that more citizens are interested in setting up their own stations to join the UP Diliman-based network. Efforts are underway to find funds for more seismometers to deploy in schools throughout the country, with the aims of expanding the network and serving as a learning and teaching platform for students interested in earthquake studies.

Meanwhile, at the UP National Institute of Physics (UP-NIP), a group of scientists from the institutes’ Instrumentation Physics Laboratory (ILP), is developing a low-cost seismic network consisting of accelerometers manufactured from commercially available components (Fig. 4). Each accelerometer costs less than $200 USD to manufacture. This network is part of a study to understand how shaking decays with distance from the source and how it is influenced by the nature of the ground underneath — called a ground attenuation relationship. Current attenuation relationships used in the country come from outside the Philippines, including experimental results from artificially induced, low-magnitude earthquakes, and data gathered directly from natural earthquakes.
 

Figure 4. Custom-made ground motion sensor (accelerometer) fabricated at the Instrumentation Physics Laboratory (IPL) of the University of the Philippines National Institute of Physics. The sensor contains the following components: (Left photo) (1) digital accelerometer; (2) development board containing the microcontroller, SD card module, and antenna for Long Range (LoRa) reception capabilities; (3) power section of board; (4) GPS module; (5) Real Time Clock (RTC) module; (6) antenna; (7) storage module; (8) power switch, (9) connection to the battery (not seen in picture) secured at the bottom of the container. (Right photo) Sensor assembled inside a closed, laser-cut acrylic sheet, with the electronic parts secured inside, connected to a pipe that serves as an extended antenna. The acrylic box is equipped with a level (button on top) to ensure horizontality of the base of the sensor. Credit: Aurelio (ongoing)

 

These complementary efforts to establish low-cost seismological observatories serve two purposes. The Raspberry Shake network promotes citizen science. The second effort led by scientists helps Philippine researchers conduct innovative but inexpensive earthquake research. Both efforts hold promise in contributing to hazard resilience in an earthquake-prone country that often lacks scientific research funds.
 

References

Anthony, R.E., Ringler, A., Wilson D.C., and Wolin, E. (2019). Do Low-Cost Seismographs Perform Well Enough for Your Network? An Overview of Laboratory Tests and Field Observations of the OSOP Raspberry Shake 4D. Seismological Research Letters. 90 (1): 219-228.

Aurelio, M. (ongoing). Project Leader: Establishing a ground attenuation relation for the Philippines using artificial blasting methods. Project funded by the University of the Philippines – Office of the Vice-President for Academic Affairs (UP-OVPAA) under the Enhanced Creative Work Research Grant (ECWRG).

Aurelio, M., Lagmay, M., Escudero, J. A., and Catugas, S. (2021a). Latest Philippine earthquake reveals tectonic complexity, Temblor, doi.org/10.32858/temblor.191

Aurelio, M., Lagmay, M., Escudero, J. A., and Catugas, S. (2021b). Philippine fault jolts Batangas again, with magnitude-5.8 quake, Temblor, doi.org/10.32858/temblor.198

Aurelio, M., Lagmay, M., Escudero, J. A., and Catugas, S. (2021c). Magnitude-5.7 Batangas earthquake puzzles researchers, Temblor, doi.org/10.32858/temblor.21

GEOFON German Research Center for Geosciences. Available at: www.geofon.gfz-potsdam.de

Holmgren, J.M and Werner, M. (2021). Raspberry Shake Instruments Provide Initial Ground‐Motion Assessment of the Induced Seismicity at the United Downs Deep Geothermal Power Project in Cornwall, United Kingdom. The Seismic Record 1 (1): 27–34.

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