Abstract
On the 16th June, 2020, a moderate earthquake (Mw = 5.2) hit the Northern Red Sea region, Egypt, that was felt throughout the Hurghada and Sharm El-Sheikh cities and the surrounding areas without any damages. The thermal anomaly before the earthquakes was widely studied with satellite data, such as NOAA/AVHRR and MODIS. The case study aims to monitor and demonstrate the possibility of any variation of the thermal anomaly of sea surface temperature (SST) before and after the 16th June 2020 earthquake and to correlate the results with the previous heat flow study (deep thermal action). The Daytime/Nighttime (SST) data are retrieved from the OBPG serves as a Distributed Active Archive Center (OB. DAAC). The outputs indicated a thermal anomaly on the June 12th, 2020 a few days before the earthquake, covered a large area around the epicenter 60 km impact area, and reached a high value on the 15th June 2020, one day before the earthquake. For the deep thermal action of the entire crust, the earthquake frequency distributions presumed from the reviewed catalogue indicated that the peak of the seismicity is concentrated close to the center of the rift axis in the Northern Red Sea. The heat flow measurements are increased toward the center of the Red Sea rift and decreased toward both sides, generating some partial melt of the rocks and producing crustal subsidence at the center of the Red Sea rift. These results are compatible with the pattern of the seismic activity and heat flow effect around the epicenter. It could be considered as a short-term precursor of the earthquake.
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1 Introduction
The establishment of earthquake forecasting systems would be helpful to mitigate the effects of earthquakes, especially for countries along tectonic plate boundaries [1]. Satellite remote sensing techniques can provide an effective method for monitoring the pre-seismic processes along active fault zones. Many statistical studies have used large earthquakes to identify a significant correlation between the pre-seismic signals and upcoming earthquakes with various analytical methods.
The earthquake precursors are the abnormal changes in the physical parameters or processes occurring before the large earthquakes. In the last three decades, many researchers have studied the thermal anomalies were observed before the large earthquakes using satellite data [2,3,4,5,6,7,8,9,10,11,12,13,14,15]. In the history of thermal anomaly research, it is undeniable that there are abnormal radiation anomalies before the large and major earthquakes, as suggested by many authors [5, 16] [17,18,19,20,21,22], as well as moderate earthquakes [18], and [19] they have studied the earthquakes with Mw > 4. Therefore, the thermal anomaly has been interpreted as a pre-seismic precursor in earthquake prediction and forecasting.
The available information and knowledge of the earthquakes should be considered during the planning and implementation of any projects to save investments and achieve sustainable development. Therefore, it is imperative to study the non-seismic phenomena such as the magnetic field variation, ground radon emission, land surface temperature (LST), sea surface temperature (SST), and outgoing longwave radiation (OLR) variations that can precede the seismic activity. Moreover, heat flow anomalies also resulted from plate tectonic processes associated with arc volcanism, hot spot traces, back-arc basins, and continental rifting.
Most of Egypt’s seismic active zones occur in the northern part of the country, including the Northern Red Sea, Gulf of Aqaba, Gulf of Suez, Cairo-Suez district, Southwest of Greater Cairo (Dahshour area), and in the Eastern Mediterranean region, as well as, the low seismic activities on the central and southern parts of Egypt [23]. The earthquakes range from small to moderate magnitudes. The significant historical earthquakes that occurred are Shadwan earthquake (Mb = 6, 1969) and Aqaba earthquake, (Mb = 7, 1995). However, instrumental earthquakes are (Beni Suef earthquake, 2006, ML = 5.2), (Asuit earthquake, 2003, ML = 5.1), and (Suez earthquake, 2014, ML = 4.3) while more recently occurred on the 16th June 2020, with MW = 5.2. This earthquake was felt throughout the Hurghada and different areas surrounding the epicenter, with no reported damage.
The Northern Red Sea was a continental rift in the process of transition from continental to oceanic spreading. It is underlain by the stretching and thinning of the continental crust, as suggested by Cochran [24, 25] and [26]. It is affected by the structural elements and tectonics of the Southeast of the Mediterranean Sea and the Northeastern corner of the African plate [27,28,29,30,31,32,33] and by the tectonic of the Sinai subplate and the Gulf of Suez-Red Sea Rift System [34,35,36]. In general, the Gulf of Suez and the Red Sea depressions were formed by the anticlockwise rotation of the Arabian plate away from the Africa plate [24].
Heat flow is generated from plate tectonic processes, whereas increasing the temperature with depth inside deep mines or earth interiors leads to heat flow anomalies. Moreover, heat flow is associated with arc volcanism, hot lavas, back-arc basins, and continental rifting. The authors have done previous heat flow studies along the Suez and the Red Sea rifts [37,38,39,40,41,42,43]. Figure 1 shows the location map of the study area with the seismicity and heat flow locations.
The local sources of heat flow include frictional heating along earthquake faults. This friction can be sufficiently intense to melt the rock, producing pseudotachylite partially. Indeed, a small amount of heat trapped by geothermal power plants located along major active faults, such as the San Andreas fault in California or active faults in Nevada, probably comes from frictional heating as rocks grind past on either side of the fault.
Figure 1 shows a conceptual diagram of the possible mechanism of stresses developed at ocean ridges due to collision of plate boundaries, venting additional hot fluid, water vapor, and other gases (from the earth's asthenosphere/lower mantle). Change in ocean thermal gradients during the seismic cycle of enhanced tectonic activity results in more heat flow than normal, and subsequent warming of the sea surface.
In this study, we have used MODIS SST data to monitor the variation of sea surface temperature before and after the 16th June 2020 Northern Red Sea earthquake to identify the thermal anomalies based on a statistical analysis of running median and inter quartile range (IQR). This method signifies the abnormality in a daily time series for 15 days before and five days after the earthquake, which can be associated with seismic activity.
This study is very important and significant because the area of interest provides a considerable resource for fishing, coral reefs, oil and gas extraction, and tourism. Moreover, the Red Sea links the European harbors to China and Eastern Asia, supporting a high volume of shipping activity. The risk and vulnerability of the Red Sea to SST thermal trends are highly expected during the current century [44], which may lead to harmful impacts on marine entities.
2 Sea Surface Temperatures (SST)
The SST is one of the most important variables used to understand the ocean and atmospheric phenomena, such as climate change, air–sea interaction, and earthquake forecasting. SST data provided by the OBPG serve as a Distributed Active Archive Center (OB.DAAC), responsible for archiving the satellite ocean biologic data produced or collected under NASA’s Earth Observing System Data and Information System (EOSDIS).
MODIS (SST) data have high confidence, as they significantly correlate to the in situ surface temperature measurements [45, 46]. Chakravarty had studied SST Variability Derived from AQUA/AMSR-E Satellite data near the Sumatra region affected by undersea earthquakes [47]. This product returns the skin temperature of the ocean by °C. The long-wave infrared (LWIR) SST products use the 11 and 12 µm spectral bands, measured by MODIS and VIIRS infrared radiometers. The validation of satellite skin SST for a climate data record and the use of shipboard radiometers can be found in [48, 49].
3 Data and Methodology
In this study, the earthquake frequency distributions from the reviewed catalogue of the Egyptian National Seismic Network (ENSN) were used to explain the distribution of the seismicity over the area. Our study concerns a moderate earthquake that occurred on the 16th June 2020, with magnitude (ML = 5.2) and hit the Northern Red Sea region, Egypt, and was felt throughout the Hurghada and Sharm El-Sheikh cities and the surrounding areas, without any damages.
In this study, the time-series of satellite remote sensing data (SST) products of the Moderate Resolution Imaging Spectroradiometer (MODIS, Level-3) are used over the Northern Red Sea region to examine the changes in oceanographic conditions before and after the 16th June 2020 earthquake. The SST MODIS data generated by the Ocean Data Processing System (ODPS) were derived from the MODIS sensors onboard the NASA Terra and Aqua platforms since November 2000. SST MODIS data products are acquired from the NASA Ocean Color Web (http://oceancolor.gsfc.nasa.gov) that have been aggregated/projected onto a well-defined spatial grid with mapping data.
In the present study, the MODIS AQUA SST Daytime/Nighttime daily products were extracted with Level-3 with 4 km spatial resolution. The SST images acquired at a wavelength of 11 µm were utilized to find the correlation between the thermal anomalies and the seismic activities before and after the 16th June 2020, Northern Red Sea earthquake for two periods (two weeks before and five days after the earthquake). Standard deviation (σ) of the mean LST values was identified, and ± 2σ (95% confidence level) interval was considered as an anomaly indicator measure. The upper bound (UB) and the lower bound (LB) were calculated by the following equations:
The SST continuity algorithm is applied for the Daytime/Nighttime observations. It is based on a modified version of the nonlinear SST algorithm (NLSST) of Walton et al., [51] that uses the empirical coefficients derived from the regression of collocated in situ and satellite measurements. This algorithm provides the product continuity between NASA’s current and future IR sensors and the heritage Pathfinder SST from AVHRRs.
For heat flow data, three profiles of heat flow composed of (stations) are used in this study. As part of this survey, 197 temperature gradient measurements were used for thermal conductivity determinations [52]. The heat flow stations were organized into three perpendicular profiles (60°) to the red sea rift and separated by 35 km from each other along the Red Sea rift. Each profile consists of 60–70 individual stations separated by 2 km apart. This pattern provides three independent measures of the heat flow variations across the rift. The locations of the heat flow profiles are shown in Fig. 2, and their measurements are given in Tables 1, 2, and 3.
The heat flow measurements indicate that the conductivity is characterized by low values ranging from 0.8 to 1.15 W m−1 K−1; these values are compatible with volcanic rocks within typical sections [53] of the lowest mean thermal conductivity values (Tuff or Andesite), which associated with high porosity. Therefore, the SST anomaly patterns overlying earthquake events are hypothesized to result from the increased heat emission from seafloor volcanic extrusions and associated hydrothermal venting.
4 Results and Discussion
The results of spatial resolution of the Daytime SST data indicated that SST variations were observed and increased anomalously by covering a large area of warm water close to the epicenter within 60 km impact area on the 12th June, five days before the earthquake. However, dramatic decreases were observed on the 13th and 14th June 2020, then increased on the 15th June, one day before the earthquake (Fig. 3). This anomaly could be related to thermodynamic processes within the earth’s crust, as thermal radiation anomaly around the epicenter 60 km impact area. Figure 4 shows the spatial resolution of the Nighttime SST data, indicating that a low anomaly is observed around the epicenter on the 13th June and followed by a high value close to the epicenter on the 14th and the 15thJune 2020. Therefore, the spatial resolution of SST Daytime/Nighttime is consistent with each other.
The statistical analyses presented in Fig. 5 show the SST Daytime & Nighttime values that were extracted from the images, based on the 60 km impact area around the epicenter. Based on the ± 2σ rule, two anomalous days in the Daytime observed on the 04th June were characterized by the lowest value, while on the 15th June indicated by the highest value. The behavior of the mean increases from the 06th June to the earthquakes’ day about ten days before the earthquake, which can be considered short‐term precursors of the earthquake. The SST in the Daytime seems stable, then decreases due to the energy released by the seismicity.
However, the results of the SST Nighttime analysis indicated that there are three anomalous days observed, one day (03rd June, characterized by negative anomalous) and the other days (the 09th and the 14th June, characterized by positive anomaly). The mean behavior indicates an increase from the 07th June to the 14th June) which is considered a short‐term precursor of the earthquake. On the 15th, the 16th June (earthquake day), a dramatic decrease occurred after the earthquake. On the other hand, no significant variation in the mean Nighttime SST is observed after the anomalous days. The findings of this study indicate that the thermal anomaly was observed 11 days before the earthquakes.
In this context, the Daytime/Nighttime SST analysis indicated that a disturbance occurred during the two weeks preceding the earthquake, which could be considered precursors of the earthquake. Therefore, this finding is consistent and compatible with previous studies [14, 54,55,56,57].
Figure 6 indicates the statistical analysis of earthquake frequencies with magnitude size; it is indicated that the peak of the seismicity is concentrated at the center of the rift and decreases on both sides (left and right). These results are consistent with the heat flow measurements for the three profiles (Fig. 7), indicating that the maximum values are concentrated in the middle of the profiles, and the heat flow values increase with depth. Moreover, Fig. 8 shows a contour map of the heat flow values with a color gradient. Light blue represents the minimum, and deep red represents the maximum. The spatial pattern of the heat flow in the figure shows that the center of the Red Sea rift is hot while the other sides are cold, indicating that the highest values are also concentrated at the center of the Red Sea rift and close to the epicenter of the earthquake. These findings are consistent with the SST results obtained from satellite data.
5 Validation of the Results
We have extracted and analyzed satellite SST data based on the non-seismic year and another event in the same area of study to validate and clarify our results. For the non-seismic year, we have used two weeks of data analysis during 1–15 November of 2018, which is characterized by no earthquakes occurring in the area of study (non-seismic activity). The results indicated that no thermal anomaly is observed (Figs. 9, 10, and 11) compared to the year 2020, in which the earthquake has occurred and is followed by a few swarms (Figs. 3, 4, and 5). For the second event in the same study area, we have extracted and analyzed satellite data before and after an earthquake occurred on the 03rd June 2004 with ML = 4.2 close the study area, during the 15th May–the 08th June 2004. The results indicate that a disturbance in surface temperature has been noticed and a significant thermal anomaly is observed on 17th and 23rd May 2004 in Daytime and the 15th, the 17th, the 19th, the 22nd, and the 23rd May 2004 in Nighttime about 10–17 days before the earthquake occurrence as shown in Figs. 12, 13, and 14.
Based on the SST analysis, we rearranged all figures and text based on the new results, which were provided in their sections. The results generally confirm the precursory behaviors of the SST for another event and compared to the same area of the non-seismic year.
6 Conclusions
The active seismic zones in Egypt occur in the northern part of the country, including the Northern Red Sea, the Gulf of Suez, the Gulf of Aqaba, the Cairo-Suez district, Southwest of Greater Cairo (Dahshour area), and the Eastern Mediterranean region, as well as the low seismic activities in the central and southern parts of Egypt. The earthquakes range from small to moderate magnitudes, except the significant historical earthquakes that been occurred in the Northeast of Egypt (e.g., Shadwan earthquake in 1969, with Mb = 6 and the Aqaba earthquake in 1995, with Mb = 7). The frequency distributions presumed from the reviewed catalogue indicated that the peak of the seismicity is concentrated close to the center of the Red Sea rift. Our study concerns the recent earthquake on the 16th June 2020 in the Northern Red Sea.
This study examines the change in the local oceanographic conditions of the SST data over the Northern Red Sea region before and after the 16th June 2020 Hurghada earthquake, based on satellite remote sensing data provided by NASA Ocean Color. This study used three heat flow profiles 197 temperature gradient measurements for thermal conductivity determinations [50].
The results of spatial resolution of the Daytime SST data indicated that SST variations were observed and increased anomalously by covering a large area of warm water close to the epicenter, within 60 km impact area on the 12th June 2020, followed by dramatic decreases on the 13th and the 14th June 2020. Then, it increased on the 15th June, one day before the earthquake; this anomaly could be related to thermodynamic processes within the earth’s crust, as thermal radiation anomaly around the epicenter 60 km impact area. While the spatial resolution of Nighttime SST data indicated that a low anomaly was observed on the 13th June, followed by a high value close the epicenter on the 14th and 15th June 2020. Therefore, the spatial resolution of the SST Daytime/Nighttime is almost consistent with each other.
The statistical analyses based on the ± 2σ rule demonstrate that two anomalous days in the Daytime were observed on the 04th June with (negative anomaly) and the 15th June with (positive anomaly). The behavior of the mean increases from the 06th June to the earthquakes’ day about ten days before the earthquake, which can be considered as short‐term precursors of the earthquake. After the earthquake occurrence, the Daytime SST seems stable, then decreases due to the energy released by the seismicity.
While the Nighttime SST results indicated that three anomalous days were observed, one day (the 03rd June with negative anomaly) and the other days (the 09th and the 14th June with positive anomaly). The mean behavior increases from the 07th June to the 14th June, which can be also considered as a short‐term precursor of the earthquake. While on the 16th June (the earthquakes’ day) and after, a dramatic decrease occurred. On the other hand, no significant variation in the mean Nighttime SST is observed after the anomalous days. The findings of this study indicate that the thermal anomaly is observed two weeks before the earthquake. Therefore, this finding is consistent and compatible with previous studies [14, 54,55,56,57].
We have extracted and analyzed satellite SST data based on the non-seismic year and another event in the same area of study to validate and clarify our results. For the non-seismic year, we have used data analysis during the period 1–15 November 2018; no earthquakes occurred in the area of study (non-seismic activity). The results indicated that no thermal anomaly is observed compared to the year 2020, in which the earthquake has occurred and followed by a few swarms. For the second event in the same area of study, we have extracted and analyzed satellite data before and after an earthquake has occurred on the 03rd June 2004 with ML = 4.2 from the 15th May to the 08th June 2004; the results indicated that a disturbance in surface temperature has been noticed and a significant thermal anomaly is observed on the 17th and the 23rd May 2004 for Daytime and 15th, 17th, 19th, 22nd and 23rd May 2004 for Nighttime about 10–17 days before the earthquake occurrence as it shown in Figs. 12, 13, and 14. The results generally confirm the precursory behaviors of the SST for another event and compared to the same area of the non-seismic year.
Moreover, the statistical analysis of the earthquake frequencies versus magnitude sizes indicates that the peak of the seismicity is concentrated at the center of the Red Sea rift and decreases toward both sides (left and right). These results are consistent with the heat flow measurements carried out by [49]. These findings suggest that seismic activity plays an important role in the heat flow and energy fluxes from the epicenter to the surrounding area. [58, 59] confirmed that the geologic faults and the large vertical cracks play an important role in heat energy (thermal) and fluid transfers in the hydrothermal systems.
Finally, the results of this study are beneficial for seismologists. It provides a guide on how the SST anomalies can be considered a precursor of the undersea earthquake (offshore). In this research, spatial and statistical analyses achieved significant results. However, to get better for a robust solution in terms of multi-earthquake precursors, it is necessary to launch a thorough search for the anomalies of sea surface parameters such as SST, sea surface winds (SSW), and sea surface pressure (SSP), or concerning multi-earthquakes precursors, such as the total electron content (TEC) and outgoing longwave radiation (OLR) over the Northern Red Sea rift during the tectonic activities with different periods.
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Acknowledgements
The authors would like to thank the Egyptian National Seismological Network (ENSN) for providing the seismological data. Also, we would like to thank the Ocean Biology Processing Group (OBPG) at NASA’s Goddard Space Flight Center for providing us with MODIS SST data, which can be downloaded directly from the https://oceancolor.gsfc.nasa.gov/ website.
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Open access funding provided by The Science, Technology & Innovation Funding Authority (STDF) in cooperation with The Egyptian Knowledge Bank (EKB).
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Mohamed, E.K., Elrayess, M. & Omar, K. Evaluation of Thermal anomaly Preceding Northern Red Sea Earthquake, the 16th June 2020. Arab J Sci Eng 47, 7387–7406 (2022). https://doi.org/10.1007/s13369-021-06524-4
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DOI: https://doi.org/10.1007/s13369-021-06524-4