At 2:18 AM Saturday 12th, June 2021, a moderate Magnitude 5.0 (md) earthquake occurred approximately 51.5 KM WSW of Güiria, Venezuela, 58.4 KM ESE of Carúpano, Venezuela, and 138 KM WSW of Port of Spain, Trinidad, and Tobago. Based on data from the United States Geological Survey, this event was located at 62.757°W and 10.474°N, at a depth of 10.0 kilometers.
Details of this event have not been made public by the U.W.I. Seismic Research Centre, the authority for seismic and volcanological information in the Eastern Caribbean. This information may change when additional data is processed by a seismologist.
There have been few felt reports, mainly from across northwestern Trinidad, mainly reporting a short jolt, lasting no longer than 1-2 seconds. Fewer have reported hearing a rumble before the shaking. You can submit felt reports to the University of the West Indies Seismic Research Centre.
There is no tsunami threat.
There are four conditions necessary for an earthquake to cause a tsunami:
- The earthquake must occur beneath the ocean or cause material to slide in the ocean.
- The earthquake must be strong, at least magnitude 6.5.
- The earthquake must rupture the Earth’s surface and it must occur at shallow depth – less than 70 KM below the surface of the Earth.
- The earthquake must cause vertical movement of the seafloor (up to several meters).
None of these conditions occurred.
Note that different seismic monitoring agencies use different methods, or several methods, for processing quake parameters across the globe. Each method has its limitations and will likely produce different results within the ranges of the data’s uncertainty. This is generally accepted within the scientific community.
The Venezuelan Foundation for Seismological Research (FUNVISIS) gave this earthquake a lower magnitude, but in a similar location and depth to where the United States Geological Survey calculated the event. According to FUNVISIS, this earthquake preliminarily registered as a light magnitude 4.5 (Mw) earthquake that occurred approximately 12 kilometers southeast of Irapa, Venezuela. FUNVISIS located the event at 62.66°W and 10.51°N, at a depth of 5.1 kilometers.
The European Mediterranean Seismological Center (EMSC) located this earthquake in a similar location to the USGS and FUNVISIS, on the Paria Peninsula.
Based on the earthquake’s calculated location, this quake occurred in seismic zone 1, within the Paria Peninsula.
Seismic zone one is a complex, and without a doubt, the most seismically active area near Trinidad. Within zone one, the South American plate is beginning to rapidly descend into the Earth’s mantle as the detached oceanic lithosphere exists at depths between 50 to 300 kilometers. (Russo et al. 1993). This zone is one of the most active seismogenic sources in the Eastern Caribbean and has the potential to generate earthquakes up to Magnitude 8.0.
At shallower levels, the North Coast Fault Zone and the El Pilar Fault are part of the Boconó-San Sebastian-El Pilar Fault system, run across Zone 1. These fault systems compensate for the stress built up as the Caribbean plate slides past the South American plate. Hence, most of these earthquakes from these fault systems are shallow to moderate between 0 to 70 kilometers.
Within 20 kilometers of the USGS, EMSC, and FUNVISIS solution, over 1,000 seismic events have been recorded, the largest being a magnitude 6.9 in August of 2018. Earthquakes in this area generally as deep as 190 kilometers, with most events occurring shallower than 25 kilometer-depth.
Earthquakes *cannot* be predicted – meaning the precise time, date, magnitude, depth, etc. cannot be known ahead of time based on current research and technology.
Generally, across the Eastern Caribbean, a seismically active area, earthquakes of this magnitude, up to M8.0 and greater, are possible and this statement has been repeated by seismologists at the U.W.I. Seismic Research Centre for decades.
Each year, over 2,200 seismic events are recorded in the Eastern Caribbean. On average, the Eastern Caribbean has seen a pattern of major (M7.0-M7.9) quakes every 20 to 30 years. That pattern has stayed true. The last major (M7.0-7.9) quake occurred north of Martinique in 2007.
Historical patterns indicate great quakes (M8.0+) on the Richter Scale have occurred every century or so in the region. The probability of another event at that level is high since the last >M8.0 earthquake occurred in 1843.
Now is the time to create or go over your earthquake preparedness plan and know what to do during, before, and after an earthquake.
Why did I hear the earthquake?
The rumbling you hear before the shaking occurs is the P-Wave, a quake’s first seismic wave creating a sound wave.
The speed of sound in the air is 330 meters per second. a single number can not describe the speed of seismic waves in the earth because it depends heavily on the material through which the waves are passing.
It is well known that sound is created in air when an oscillating object is in contact with it. The sound really is oscillations in pressure, displacement, and speed of the air, in concordance with the object creating them.
Now, the seismic waves themselves include oscillations of the earth’s surface, which is in contact with the air. Therefore, they cause oscillations in the air. However, the frequency of these oscillations is so low that we hear the least part of them as sound. Still, the frequency of the fastest waves, the P-waves, may be more than 30 Hertz and thus be audible as sound. The sound-induced by seismic waves in the air have been compared to the boom in underground stations when a train is approaching.
We normally sense P-waves as an earthquake to a lesser degree than, for instance, the S-waves following them. If an earthquake has not been very strong or we are reasonably far away from its center, we will not at all sense the P-waves as an earthquake but only hear the sound-induced by them in the air. Still, we may feel the S-waves quite clearly and then other waves, which often arrive later, especially at a distance.