Abstract
Paper describes triggered seismicity to 200 km distance and for a decade due to the 2001 M w7.7 Bhuj earthquake. The Kachchh region is seismically one of the most active intraplate regions of the World due to the occurrence of two large earthquakes 1819 (M w7.8) and 2001 (M w7.7). Though, it has high hazard but was known to have low seismicity in view of the occurrence of fewer smaller shocks. However, the status seems to have changed after 2001. Besides the strong aftershock activity for over a decade, seismicity has spread to nearby faults in Kachchh peninsula and at several places southward for 200 km distance in Saurashtra peninsula. Beyond the rupture zone of the 2001 Bhuj earthquake, more than 40 mainshocks of M w ~ 3–5 have occurred at 20 different locations, which is unusual. The increased seismicity is inferred to be caused by stress perturbation due to the 2001 Bhuj earthquake by viscoelastic process. In Saurashtra, over and above the viscoelastic stress increase, the transient stress increase by water table rise in monsoons seems to be affecting the timing of mainshocks and associated sequences of earthquakes.
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1 Introduction
Gujarat state in western India is geographically divided into three parts: the Kachchh peninsula, the Saurashtra peninsula situated south of it with an intervening gulf, and the mainland east of these peninsulas. Prior to 1999, seismicity was monitored in Gujarat with up to 25 analog seismographs. Though the Kachchh and Saurashtra regions were not well monitored until 2000, even then it is believed that the existing network has not missed any earthquake of M w > 3 in Gujarat in last four decades. Bhuj station was upgraded with a digital broadband seismograph in 1999, and Dharoi broadband seismograph station was started in 2000. From 2001, a network of up to ten broadband seismograph stations was operated in Kachchh (Mandal et al. 2004a, b). Starting mid-2006 a dense network is operated by Institute of Seismological Research (ISR), Gandhinagar, which currently has 60 broadband seismographs and 50 accelerographs in and around Gujarat (Chopra et al. 2008a). The detectability is M w2.0 in Kachchh active area and M w2.5 in other areas.
Prior to 2001, Kachchh had experienced three large earthquakes: M w7.8 Allah Bund (24.00°N 69.00°E) earthquake in 1819, M w6.3 Lakhpat (23.80°N 68.90°E) earthquake of 1845, and M w6 Anjar (23.30°N 70.00°E) earthquake in 1956. Smaller shocks include seven earthquakes of magnitude 5–5.6 and only 71 of M w3.5–4.9. In Saurashtra, the two significant earthquakes were 1919 M w5.7 Ghogha (22°N 72°E) and 1938 M w5.7 Paliyad (22.40°N 71.80°E).
During the first decade of the twenty-first century besides the aftershocks of 2001 earthquake, seismicity is substantially high compared to last twenty decades in Kachchh and also in Saurashtra. The sudden upsurge of seismicity appears to be influenced by stress perturbation due to the stress drop estimated to be 200 bars due to the 2001 Bhuj earthquake of M w7.7 (Bodin et al. 2001). Paper describes the details of the increase in seismicity and probable cause of it.
2 Seismicity of Kachchh rift
Earthquakes (up to M w7.8 level) occur in about 250 km × 150 km size Kachchh rift along E–W faults. The entire crust is brittle as evidenced by focal depths of earthquakes from near surface to 36 km. Sometimes hidden faults are active. As most parts of the basin experience seismicity, it is critically stressed. The pre-existing faults get reactivated due to the strain accumulation or fault weakening. Several studies (monitoring of seismicity through 25 or more local broadband seismographs, active fault investigations, geophysical surveys, GPS network) for the 2001 Bhuj earthquake and aftershocks have given insights into seismogenesis of earthquakes in intraplate regions. The main shock and most of the aftershocks occurred along a south dipping (~45°) hidden fault from 10 to 34 km depth. Three-dimensional velocity structure obtained from inversion of travel times of P and S waves of aftershocks indicates a high Vp magmatic body at regional scale and in 10–34 km depth range. This body is probably acting as a stress concentrator due to the density and rigidity contrast. A low velocity fluid-filled patch in 20–30 km depth range in the hypocentral zone might have acted as an asperity (Mandal et al. 2004a, b). In the epicentral region of the 2001 earthquake, lithosphere is inferred to be hot and thin (only 70 km as compared to normal 100 km) and crustal thickness is also thin (34 km as compared to 40 km in the surrounding region) due to rifting at around 184 Ma. Restructuring of this warm and thin lithosphere might have occurred due to the thermal plume at 65 Ma (Mandal and Pandey 2010).
3 Increased seismicity of Kachchh
Locations of seismograph stations operated since mid-2006 are shown in Fig. 1. Location accuracy since 2001 is better than 1 km from SEISAN program and better than 0.1 km from HYPO DD program in Kachchh seismic area. For Saurashtra, the location accuracy is 2 km from SEISAN and 0.1 km from HYPODD. For epicenter locations, velocity model of Mandal and Pujol (2006) for Kachchh region is being used and is given in Table 1 and Fig. 2. For Saurashtra region, velocity model of Kaila et al. (1981) is being used and is given in Table 2 and Fig. 3. In the SEISAN program, Vp/Vs is taken as 1.73. In some parts of the Kachchh area, it is likely to be different. However, it is difficult to use different Vp/Vs values in the location program. Moment magnitude M w is estimated and the catalog of Gujarat earthquakes (http://isr.gujarat.gov.in) has been homogenized to M w values. M L is given for M < 2.
During 2001, the aftershocks in Kachchh were confined to 20 km radius of the mainshock epicenter. During 2006, an earthquake of M w5.7 and associated sequence was triggered along the Gedi Fault about 60 km NE and M w5.6 along the South Wagad Fault in the east direction (Fig. 4). During the first decade of the twenty-first century due to the aftershocks of 2001 earthquake, seismicity is substantially high in Kachchh (Fig. 5, Tables 3, 4, 5, 6) compared to last twenty decades. The aftershock activity includes over 10,000 shocks of 1–2.9, 2,401 shocks of M w3–3.9, 357 shocks of M w4–4.9, and 20 shocks of M w ≥ 5.0, which have occurred during 2001–2010. In this region, M w5.7 level seismicity continued until mid-2006. From mid-2006, there is no shock of M w ≥ 5.0; however, shocks of M w < 5.0 are continuously occurring with earthquakes of M w > 4 once every 2 months and five or so of M w > 3 every month.
Nevertheless, the mainshock number away from aftershock zone is double of the decadal frequency in previous two decades (Table 3). During 2006–2008, several nearby faults in Kachchh up to 100 km distance from Bhachau are activated with M w4–5.7 earthquakes along South Wagad, Gedi, Allah Bund, Island Belt, Gora Dungar, Banni, and Karol Hill Faults (Fig. 5). Locations of mainshocks in Kachchh and Saurashtra since 2000 are shown in Fig. 6. The trends of shocks and their associated faults in Kachchh are better seen in Figs. 7 and 8. All these faults experience sporadic earthquakes since then. Other than the aftershock activity of the 2001 Bhuj earthquake, 20 mainshocks (of M w3–5) occurred at 16 different locations in Kachchh. Focal depths are about 10–35 km in the aftershock zone of the 2001 Bhuj earthquake. Similar focal depths may be along the Island Belt Fault but shallower along some other faults like Gedi and Gora Dungar Fault. Only the Gedi earthquake of March 7, 2006, of M w5.7, the Gora Dungar October 28, 2009, earthquake of M w4.6, and the two earthquakes of January 8 and August 13, 2011, of M w4 and 4.5, respectively, had associated sequences of up to about 50 shocks of magnitude ≥1. More details of these few clusters and other significant activities are as follows:
2006:
Gedi Fault (23.79 70.73) M max5.7 on March 7, sequence for a few years, mainshock indicated reverse movement with right-lateral strike-slip component along a E–W trending and south dipping (61°) plane, which agrees with the Gedi Fault (Mandal et al. 2008). M w4.8 (mb4.9) aftershock followed a month later. The cluster of earthquakes in the Gedi Fault region for a few months had a number of shocks. The shocks have continued to occur once in a while along the Gedi Fault totaling over 50 earthquakes of magnitude ≥1 in last 5 years.
2006:
Island Belt Fault (Lat: 23.92 N, Lon: 70.44E, Depth: 29 km) M max5.0 on February 03 (Mandal et al. 2008). Sporadic shocks of magnitude up to 4 have occurred along IBF and its western extension, the Allah Bund Fault.
2009:
Gora Dungar Fault (23.71N 69.91E) M max4.6 on October 28, 2009, the cluster of earthquakes in the Gora Dungar had 38 earthquakes, and the duration of the cluster was 2008-04-14 to 2011-01-05.
2011:
Rapar (23.46N 70.36E) M max4.0 on January 8. The sequence included 48 shocks in 10 km radius for 10 days.
2011:
8 km SW of Rapar (23.552N 70.574E) May 23
2011:
10 km NE of Vamka (23.462 70.411) M max4.6 on August 13
4 Seismicity of Saurashtra
Locations of shocks in Saurashtra and their trends are shown in Figs. 9, 10, and 11. Saurashtra region is bounded on all the sides by boundary faults. However, no seismicity has been noticed along these faults except the West Cambay Fault that borders the eastern side and has experienced earthquakes of magnitude up to 5.7. Off coast southeastern part of Saurashtra near Rajula (20.6N 71.4E) M5 earthquake occurred on August 24, 1993, along with two other shocks of M w3–4. The interior part of Saurashtra is either covered by volcanic Deccan Traps or covered by quaternary deposits due to which no clear fault has been identified and neither any significant earthquake has occurred. The earthquakes in this region are likely to be associated with small faults corresponding to Proterozoic Aravali trends in NW direction or Mesozoic Narmada trend in ENE direction. The focal depths are up to 15 km, indicating that most of the stresses are concentrated in the upper 15 km. Faults in Kachchh (Chandrasekhar et al. 2005; Mishra et al. 2005) and Saurashtra (Mishra et al. 2001; Chandrasekhar et al. 2002) could be extending to crustal depths and are associated with block movements and high-density mafic intrusive as indicated by gravity anomalies.
5 Increased seismicity of Saurashtra
The Saurashtra region has been experiencing stray tremors once in a while in the last two centuries. In the last three decades of 1970s to 1990s, there were 3–5 shocks per decade (Tables 7 and 8) and had two damaging earthquakes of M w5.7 in 1919 and 1938. During 2000, the Bhavnagar (21.7N, 72.3E) M max4.2 earthquake on September 12 caused wide cracks in tens of houses. A foreshock of M3.6 on August 9 was also damaging. It caused subsidence of several houses. Some 50 shocks were felt during August to October 2000. During the 1st decade of twenty-first century, Saurashtra peninsula experienced damaging earthquakes accompanied by long sequences. The three most significant are as follows: (1) 2006 M w4.0 Khankotda area in Jamnagar district (2) 2007 M w5.0 Talala, Junagadh, and (3) 2007 M w3.7 Sayala, Surendranagar (Chopra et al. 2008b). There were thirteen other sequences and some 12 tremors of M w ~ 3 to 4 (without sequences) at different locations in Saurashtra (Fig. 4; Table 6 and the list below).
Examples of Swarm-type earthquake sequences in Saurashtra:
1938:
Paliyad (22.4N 71.8E), July–August, Swarm had four shocks of magnitude more than 5.0, M max5.7. More than 190 shocks felt with rumbling sound.
2000:
Bhavnagar (21.78N 72.31E) August 9–25, M max3.6 on August 10, 43 aftershocks. Cracks in tens of houses.
2000:
Bhavnagar (21.7N 72.3E) August–October: M max4.2. Some 132 foreshocks and aftershocks in the magnitude range of 0.5–3.8 were located (Bhattacharya et al. 2004). Eleven shocks of M ≥ 3. Most shocks were felt with subterranean sounds. Cracks in a number of houses and low-rise buildings.
2000:
Una-Tulsi Shyam, Girnar Hills (21.02N 70.99E) M w4.6 on August 13, a few aftershocks. Wall cracks and collapses in 75 houses in Gir Gadhada and in several houses in Una.
2001:
Sasan Gir area (Haripur village, Talala, Junagadh, 21.16N 70.54E), October–December (2 months), M max3.2 on November 11, 1689, shocks recorded, 9 shocks of M w ≥ 3. Many accompanied by blast sounds with occasional shaking.
2003–2004:
Sasan Gir area (Haripur, 21.16N 70.54E), September 03–January 04, M max3.1 on January 29, shocks felt with rumbling sound.
2003:
Sasoi Dam near Lalpur magnitude 3.0 and numerous small shocks felt with blast-like sounds.
2006:
Lalpur (22.2N 69.9E) September–October 2006, M max4.0, 200 shocks felt with blast sound.
2006:
Kalavad, Khankotda (22.3N 70.22E) September–October 2006, M max4.0, September 30, 200 shocks felt with blast sound. Slight damage reported to some adobe-type houses. Some 50 hypocenters of M w ~ 2–3.3 were located by local network.
2007:
Khankotda (22.33N 70.22E) M max3.2 on September 2.
2007:
Vijrakhi (22.4N 70.2E) August–October 2007 M max3.5 on September 9, over 200 shocks felt with blast sound. Slight damage reported to some adobe-type houses.
2007:
Ankolwadi, about 15 km SE of Sasan Gir, Talala (21.08N 70.73E) M max3.1 on December 10. Swarm of 50 foreshocks and aftershocks of M0.5–2.9 during October 4–10 and December 10–20 indicating about 50 km long ENE trend (ISR Annual Report 2008).
2007:
Verad, Bhanvad (21.93N 69.82E) M max2.9 November 11, 12 foreshocks and aftershocks of magnitude 0.5 to 2.9 during August to December 2007.
2008:
Chotila, Surendranagar rm of hundreds of shocks from 2007 and continued through 2011.
2008:
Bhanvad, Jamnagar (21.90N 69.96E) M max3.6 on October 4, 6 foreshocks and aftershocks of magnitude 0.5 to 2.9 during October to December 2008.
2010:
Kalavad, Jamnagar (22.20N 70.37E) M max2.8 on September 6, 55 foreshocks and aftershocks of magnitude 0.5 to 2.9.
2010:
Advana, Porbandar (21.90N 69.70E) M max3.0 on September 23, 50 foreshocks and aftershocks of magnitude 0.5 to 2.9.
2010:
Bhanvad, Jamnagar (21.91N 69.75E) M max2.8 on September 25, 20 foreshocks and aftershocks of importance 0.5 to 2.7.
2010:
Khankotda, Jamnagar (22.29N 70.24E) M max3.4 on November 25.
2010:
Khankotda, Jamnagar (22.28N 70.25E) M max3.4 on November 28, 65 foreshocks and aftershocks of magnitude 0.5 to 2.9.
2010:
Motikhavadi, Jamnagar (22.36N 69.98E) M max3.0 on September 29, 56 foreshocks and aftershocks of magnitude 0.5 to 2.9.
2011:
Sasan Gir area (21.09N 70.45E), October–December 2011, M w5.1 on October 20 at about 8 km SW of 2007 epicenter. Walls collapsed in about 30 houses and wide cracks in about hundred houses. Over 300 shocks of magnitude ≥1 located including nine shocks of M w3–3.9 and two shocks M w4.0 and M w4.1. The mainshock indicated left-lateral strike-slip along an ENE trend. Shocks have occurred along a 40-km-long ENE trend. (ISR Tech. Report, 2011).
In contrast, the earlier twenty decades experienced only a sequence during 1938 for M w5.7 Paliyad earthquake and the other for earthquake of M w4.2 Bhavnagar (21.72°N 72.16°E) in 2000 as listed above. Soon after the 2001 Bhuj earthquake, two sequences occurred during 2001 and 2003–2004. However after 2006, earthquakes of M w3.0–5.0 with long sequences of foreshocks and aftershocks started occurring at a number of places along small faults (Chopra et al. 2008b). The sequences that have continued for several years are at (1) Khankotda, Kalavad, Sanala, Motikhavadi, and Bhanvad areas in Jamnagar district, (2) Talala in Junagadh district, and (3) Sayla-Chotila in Surendranagar district. Shocks have recurred every year since 2006 in Jamnagar district, since 2007 in Talala, Junagadh district and Surendranagar district. At these three sites, several hundred magnitude ≥0.5 shocks were recorded on local networks of broadband seismographs. Earthquakes of M w4.8 and M5.0 that occurred in November 2007 in Talala and M w4.0 in Kalavad in September 2006 caused damage to numerous houses. The areal extent of the epicenters is up to 30 km. The shocks are shallower than 10 km and are associated with subterranean sounds. A number of short sequences localized in small areas occurred during 2010 at Khankotda, Kalavad, and Motikhavadi in Jamnagar district.
Khankotda and adjoining villages in Jamnagar district of Gujarat experienced over 200 shocks during September—October 2006, out of which about 50 shocks of magnitude ~2–3.3 were located. The shocks were felt with blast-like subterranean sounds. The largest tremor of magnitude 4.0 occurred on September 30, 2006 (22.31°N 70.22°E, at focal depth of 5 km). The sequence was monitored with local seismic stations. The activity recurred from August 11, 2007, after heavy rainfall in Khankotda, but this time spreading northward to Vijrakhi area 15 km short of Jamnagar, which is major city and petro-hub. The maximum magnitude was 3.4 on September 9, 2007, located close to Khankotda. The tremor caused cracks in a few houses in Khankotda. Over 200 shocks were felt and over 50 of magnitude ~2 to 3.4 were located during August–September 2007 in 50 days from regional network (and with local network since September 8, 2007). A shock of M w2.9 on September 7, 2007, caused minor cracks in a few houses at Vijrakhi village. Seismicity in Khankotda area continued to recur for further 3 years from 2008 to 2010. Most of the epicenters are located in a 15-km-long NW trend between Vijrakhi and Khankotda villages (Fig. 9). Some shocks have occurred about 15 km west of this trend along a NNW–SSE lineament. These lineaments are along dolerite dykes.
During August–September 2003, numerous events followed by blast-like subterranean sounds were felt by local people in and around Sasoi dam (filled in 1954) in Lalpur area of Jamnagar. The maximum intensity observed was around IV, which corresponds to magnitude 3.0. The swarm-type earthquake sequence was highly localized and subsided in a month’s time. This activity was associated with a major N–S-trending dyke with two offsets in E–W and NW–SE directions (Srivastava and Rao 1997).
Sasan Gir Asiatic Lion Sanctuary area (Haripur village closest to the epicenter) in Talala taluka (120 km south of Khankotda) of Junagadh district experienced earthquake swarms in 2001, 2004, and 2007 with maximum magnitude 3.2, 3.4, and 5.0, respectively. Earthquakes of M4.8 and M5.0 that occurred in November 2007 in Talala caused damage to a number of houses. Geological investigations and satellite investigations in the Sasan Gir area revealed existence of a N–S trending and about 20-km-long strike-slip fault. The moment-tensor fault mechanism indicated a right-lateral slip along a NNW trend.
The shocks in Advana of Porbandar district to Bhanvad, Sanala, and Jam Jodhpur areas of Jamnagar district form a E–W trend of about 40 km length.
The shocks near Chotila-Sayla area in Surendranagar district have recurred every year since 2006 after the monsoons. The socks define a 40-km-long NW trend. The M max3.1 (22.51, 71.45) occurred on March 15, 2008.
All these sequences in Saurashtra occurred mostly during September to November after heavy rains. The unusual seismicity in Saurashtra since 2001 is suggested to be due to stress increase by stress perturbation due to 2001 Bhuj M7.7 earthquake up to 200 km distance in the south. However, the sudden rise of water table by 30 M from pre- to post-monsoon is inferred to cause 3 bars stress change which triggers small to moderate earthquakes at particular period of the year.
In Khankotda, the ground water–level fluctuation from summer to monsoon season is reported to be quite high. Ground water in summer is usually encountered at a depth of around 25 m, but after rains it is available near surface. During 2006 and 2007, water table is reported to have risen by about 24 m. Ground water table measurements are done quarterly in several observation wells of Gujarat. The values of four wells in nearby areas are depicted in Fig. 12. The well at Motimatli is in earthquake zone at a distance of 6 km NE of Khankotda. It indicates 18-, 6-, and 18-m change during 2005, 2006, and 2007, respectively. During 2006, the seismicity started a fortnight after 57-mm rainfall on August 3 and largest shock of M w4 of September 30 occurred 12 days after 59-mm rainfall on August 18. Rise in water table may be following the rainfall in a couple of days only as water table would be close to surface.
6 Modes of post-seismic deformation and possible ways of stress increase
The possible modes of post-seismic deformation and stress perturbation currently invoked are: short-time triggering of earthquakes due to passage of seismic waves (not noticed in Gujarat), the shear deformation as adjustment process (became negligible in the 2001 Bhuj earthquake zone since 2005 (Fig. 13) as deduced from only 2–3 mm/year movements of GPS stations), co-seismic Coulomb stress increase (the NE migration of seismicity to Gedi area which is in the zone of decreased stress (Mandal et al. 2007) and seismicity up to 200 km distance can’t be explained by this mechanism). Hence, stress transfer by viscous flow of lower crust and upper mantle both upwards and outwards across a broader region (Freed et al. 2007) which may explain the stress increase and triggering of earthquakes even after some years has been modeled.
6.1 Temporal variation of Coulomb stress
The calculation of Coulomb stress changes is based on the concept of a critical Coulomb failure stress, σc, in which
where τ is shear stress, σn is normal stress, p is pore pressure, and μ is the coefficient of friction (Jaeger and Cook 1979; Scholz 2002). As the absolute stress field is difficult to determine, we calculate stress changes over a period of time using the relation
where Δσc represents change in stress and μ′ is the apparent friction, which takes into account reductions in friction due to the pore pressure changes. A positive Coulomb stress change implies that a fault is brought closer to failure, whereas a negative Coulomb stress change implies that a fault is brought farther away from failure.
Here, we calculate the amount of Coulomb stress present in Kachchh and Saurashtra regions even after some years by considering contribution from post-seismic deformation since the 2001 Bhuj earthquake. Our objectives were to determine the role of post-seismic mechanism in the evolution of stress since 2001 and to determine how stress at subsequent hypocentres was influenced.
We calculated the post-seismic stress change in the Gujarat region due to the 2001 Bhuj earthquake considering viscoelastic mechanism using EDGRN/EDCMP code developed by Wang et al. (2003), which is based on the representation of a layered spherical earth with elastic–viscoelastic coupling. We adopted the earthquake source parameterization of Yagi and Kikuchi (2001). Strike, dip, rake, and seismic moment are 78°, 58°, 81°, and 2.5 × 1020 Nm, respectively. The model rupture is 75 km long and 35 km deep. The variable slip distribution of Yagi and Kikuchi (2001) was taken to calculate the post-seismic stress transfer. The velocity model of Kachchh was adopted from Mandal and Pujol (2006). Viscosity of lower crust/upper mantle (at a depth ~34 km) was taken as 2 × 1019 Pa s (Chandrasekhar et al. 2009).
Figure 14 shows the stress transfer in bars after 6 years of the 2001 Bhuj earthquake. The calculated post-seismic stress changes (+1 bar) following the Bhuj earthquake seem to correlate with the migration of seismicity toward east along the SWF and toward NW in the Banni area. The Gedi area in this model also falls in a zone of stress decrease. Lobe of positive stress change (0.1 bars) is also observed in Jamnagar, Junagadh, and Surendranagar region of Saurashtra, which may be sufficient for triggering seismicity in those regions. Hence, the viscoelastic process appears to be the plausible mechanism for long distance and delayed triggering of earthquakes by migration of stress pulse generated by the 2001 earthquake with diffusion rates of 5–30 km/year or area growth of 4,000 sq km/year contributing stress vertically upwards from lower crust and upper mantle to distance of 200 km in 6 years. The increased stress in the lower crust or upper mantle appears to be transmitted upwards to near surface depths. It may cause more vertical deformation. Unusually high vertical deformation is detected by GPS to the tune of up to 13 mm/year and by InSAR measurements up to 40 mm/year at several places in Kachchh (ISR annual report 2009; Sreejith et al. 2011).
Post-seismic deformation results in three ways: after-slip of the fault zone, poroelastic rebound, and viscoelastic relaxation of the mantle and lower crust. The shallow afterslip itself (Smith and Wyss 1968) can lead to an increase in stress (Freed 2005). But afterslip may not be the contributor to post-seismic stress transfer in Gujarat region as very negligible (~2–5 mm/year), horizontal deformation is observed through GPS measurements. Poroelastic rebound, which is deformation driven by fluid flow that relieves pressure differences caused by the earthquakes, is generally considered close to the fault and near geometric complexities such as fault stepovers and bends (Freed 2005). However, it appears to act in Gujarat in the same fashion as stress transfer through pore pressure diffusion invoked for reservoir-triggered seismicity (Talwani et al. 2007). The post-seismic models in which the mantle is linear and viscoelastic predict transient deformations that always extend to great distance, even a long time after earthquake (Savage and Prescott 1978). Hence, both poroelastic and viscoelastic mechanisms may be potentially important to post-seismic deformation in this area.
7 Discussions
Aftershocks of the 2001 earthquake are continuing for over a decade. Post-seismic deformation can be large and long lasting (Wang 2007). For example, the post-seismic deformation for 1964 Alaska earthquake is 15–20 mm/year even after 46 years (Suito and Freymueller 2009).
Besides the aftershocks, seismicity in Gujarat has substantially increased in the first decade of the twenty-first century. The seismicity in Kachchh was found to have been extended first eastward and north-eastward and then in the north along newly activated faults from 2006 to 2008. In Saurashtra, at unusually large number of places, swarm type of activity is associated with earthquakes of M3.5–5. This is unusual comparing the catalog of last 200 years. The seismicity increased in Saurashtra region also with short or long sequences of earthquakes: during 2001–2007 and through 2011 in Sasan Gir of Talala area of Junagadh district, in 2003 near Sasoi dam area of Jamnagar district, from 2006 through 2010 at Khankotda area of Jamnagar district and several spots like Kalavad, Vijrakhi, and Motikhavadi area south of Jamnagar and Chotila-Sayla area of Surendranagar district, and in 2010 at Advana in Porbandar district to Bhanvad, Sanala, and Jam Jodhpur areas of Jamnagar district forming an E–W trend of about 40 km length. During the earlier 20 decades, only one strong sequence happened in 1938 at Paliyad and two small sequences in 2000 at Una and Bhavnagar. A large number of sequences and several other individual shocks suggest that the seismicity since 2001 in Saurashtra may be affected by the 2001 Bhuj earthquake and same in Kachchh region. The stress increase may be due to viscoelastic process or stress pulse migration due to some other process.
Worldwide, there are many examples to indicate that one earthquake can trigger another by stress transfer. Stress changes in the crust due to an earthquake can hasten the failure of nearby or far faults and induce earthquake sequences in some cases. It has been shown that viscous flow in the lower crust or upper mantle after a moderate or major earthquake can lead to significant increases in stress and strain in the seismogenic upper crust (Freed and Lin 2001; Stein 1999; Harris et al. 1995; Pollitz et al. 2003).
Long-distance and delayed triggering of earthquakes in space or time, or both, is less documented. Some cases are reported: (1) One example of long-distance, short-time triggering is due to 1992 Landers earthquake that triggered earthquakes at remote distances after a few minutes or hours (Hill et al. 1993), (2) example of intermediate-distance, long-time triggering is for inland earthquakes in northern Honshu (Rydelek and Sacks 1990), and (3) an example of short-distance, long-time triggering is of the 1999 Hector Mine M w7.1 earthquake triggered by the 1992 Landers M w7.3 earthquake 20 km away (Freed and Lin 2001; Zeng 2001; Pollitz 2002). Sometimes local process may also cause further increase in stress.
It appears that the stress pulse due to 20 MPa stress drop has migrated via viscoelastic process (rheology change) in lower crust and upper mantle. Unusually, all the surrounding faults of 2001 epicentral zone became activated by 2008. In Saurashtra also, at unusually high number of places swarm type of activity is associated with earthquakes of M w3.5–5. This is unusual comparing the catalog of last 200 years. Though the stress pulse may propagate horizontally through lower crust and upper mantle, it is transferred vertically to faults near the surface.
Gujarat region seems to be critically stressed as evidenced by the occurrence of earthquakes along several faults. It is well known that the critically stressed faults can be triggered by small stress perturbation. To et al. (2004) estimated that due to the 1819 earthquake, 0.1 bar Coulomb stress increase near the epicenter of the 2001 Bhuj earthquake has influenced the 2001 earthquake. Viscoelastic modeling indicates stress perturbation of up to 1 bar in Kachchh and 0.1 bar in Saurashtra seismic zones. Hence, the sudden appearance of earthquakes along several faults in Kachchh and Saurashtra to 200 km distance from the 2001 Bhuj earthquake epicenter might have been triggered by stress perturbation.
In Saurashtra region, less than 1 bar stress increase due to the 2001 Bhuj earthquake may not be enough and 2–3 bar stress increase due to the rapid rise in water table by 20–30 m then triggers the seismicity soon after monsoons. In the Kachchh region, the stress increase of 1 bar may be enough for the triggering effect.
It has been observed that the changes in Coulomb stress ranging between 0.1 and 1 bar and sometimes even smaller than 0.01 bars can trigger future seismicity (Reasenberg and Simpson 1992; King and Cocco 2000; Rajput et al. 2005; Raju et al. 2008), even though these values are much lower than the stress drop in an earthquake (commonly several bars to hundred bars). Triggering does not mean that the coseismic stress changes associated with an earthquake are enough to generate another earthquake at originally stress-free location; it means that the stresses at the location of the ensuing shock are already close enough to failure that the first earthquake can trigger the second one by introducing a positive increase in changes in Coulomb stress such as to move it into the failure regime (Papadimitriou and Sykes 2001; Papadimitriou 2002; Papadimitriou and Karakostas 2003).
Hence, it can be said that the heightened seismicity in Kachchh and Saurashtra during the 1st decade of the twenty-first century is triggered by stress increase due to the 2001 Bhuj earthquake. In Saurashtra, the local stress increase due to water table rise after the monsoons influences the timing.
8 Conclusions
In the first decade of the twenty-first century, unusually several faults in Kachchh and Saurashtra have become active maybe because of stress increase of up to 1 bar due to the 2001 devastating Bhuj earthquake by viscoelastic process. In Saurashtra, 30 m rise in water table during monsoons added additional 3 bars stress probably causing triggering of earthquakes during September to November during several years. The faults in Kachchh are well recognized and have potential of up to M7 or more earthquakes. In Saurashtra, the seismicity trends indicate 20- to 40-km-long faults that have potential of M6 earthquakes. The activeness of 50- to 100-km-long faults in Kachchh may indicate higher probability of occurrence of M6–7 earthquakes along these faults, and activeness of 20- to 40-km-long faults in Saurashtra may indicate higher probability of M6 earthquakes along such faults. The faults in Saurashtra are masked due to Deccan Traps or Quaternary cover. However, gravity data indicate the presence of faults. The two prominent trends are NW Proterozoic Aravali trend and ENE Mesozoic Narmada trend.
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Rastogi, B.K., Aggrawal, S.K., Rao, N. et al. Triggered/migrated seismicity due to the 2001 M w7.7 Bhuj earthquake, Western India. Nat Hazards 65, 1085–1107 (2013). https://doi.org/10.1007/s11069-011-0083-3
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DOI: https://doi.org/10.1007/s11069-011-0083-3