Abstract
The NW–SE trending Zagros orogenic belt was initiated during the convergence of the Afro–Arabian continent and the Iranian microcontinent in the Late Cretaceous. Ongoing convergence is confirmed by intense seismicity related to compressional stresses collision-related in the Zagros orogenic belt by reactivation of an early extensional faulting to latter compressional segmented strike–slip and dip–slip faulting. These activities are strongly related either to the deep-seated basement fault activities (deep-seated earthquakes) underlies the sedimentary cover or gently dipping shallow-seated décollement horizon of the rheological weak rocks of the infra-Cambrian Hormuz salt. The compressional stress regimes in the different units play an important role in controlling the stress conditions between the different units within the sedimentary cover and basement. A significant set of nearly N–S trending right-lateral strike–slip faults exists throughout the study area in the Fars area in the Zagros Foreland Folded Belt. Fault–slip and focal mechanism data were analyzed using the stress inversion method to reconstruct the paleo and recent stress conditions. The results suggest that the current direction of maximum principal stress averages N19°E, with N38°E that for the past from Cretaceous to Tertiary (although a few sites on the Kar-e-Bass fault yield a different direction). The results are consistent with the collision of the Afro–Arabian continent and the Iranian microcontinent. The difference between the current and paleo-stress directions indicates an anticlockwise rotation in the maximum principle stress direction over time. This difference resulted from changes in the continental convergence path, but was also influenced by the local structural evolution, including the lateral propagation of folds and the presence of several local décollement horizons that facilitated decoupling of the deformation between the basement and the sedimentary cover. The obliquity of the maximum compressional stress into the fault trends reveals a typical stress partitioning of thrust and strike–slip motion in the Kazerun, Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones that caused these fault zones behave as segmented strike–slip and dip–slip faults.
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Introduction
The stratigraphy of the Zagros is well known because of its oil and gas potentials; however, critical questions remain about the relationship between the stress regime during the initiation of the Zagros orogenic belt and its later evolution. For example, as in some other collisional orogeny like Himalaya–Tibet orogeny, is the compressional direction almost parallel to the plate motion? What is the variation in the orientation of the principal stresses over time? Previous work (e.g., Vernant et al. 2004; McQuarrie et al. 2003) suggested that the convergence path between the Iranian microcontinent and the Afro–Arabian continent from the Mesozoic to the recent has been oblique and is deviated from N–E to N (Fig. 1). Is there data to support these proposed compressional trends over time? The deformation in the sedimentary cover is decoupled from the basement (likely at the level of the Hormuz salt). Is there any variation in the stress direction between the sedimentary cover and the upper gneissic crust? Unlike the locations of the studies by Lacombe et al. (2006) and Navabpour et al. (2007), the locations chosen in our study were close to fault zones. In the vicinity of the main lateral fault zones (e.g., Kazerun and Kar-e-Bass fault zones), is the stress regime similar to that in other parts of the Zagros orogenic belt? In other words, is there any significant deviation of compressional direction in the vicinity of the major lateral fault zone? This work will have a far reaching implication in seismicity of the Zagros orogenic belt.
In this study, we inferred the paleo and recent stress regimes based on the inversion of fault–slip data and earthquake focal mechanisms. We also used these results to test the role of the infra-Cambrian Hormuz salt (Mukherjee et al. 2010; Mukherjee 2011, 2013) as a décollement horizon between the sedimentary cover and the basement by comparing the results of the inversion of the fault–slip and earthquake focal mechanism data. Inversion of earthquake focal mechanisms has been proposed by several studies (McKenzie 1969; Angelier 2002; Otsubo et al. 2008). The paleo-stress analysis is referred by some authors as Angelier (1979, 1994), Yamaji (2000a, b), Zalohar and Vrabec (2007), and Misra et al. (2014) using the inverse problems. Inversion of earthquake focal mechanisms and fault–slip data is based on the Wallace–Bott hypothesis which assumes that striation slip occurs on each fault plane in the direction and sense of the maximum resolved shear stress. The traditional stress inversion approaches look for the best-fit stress tensor by minimizing or maximizing some object function which is defined through a summation of the compatibility functions for all fault–slip data (Zalohar and Vrabec 2007).
The Fars area is a key region to understand the tectonic and kinematic evolutions of the Zagros orogenic belt from the Cenozoic to the recent times. The study area is located in the central part of the Zagros Foreland Folded Belt (F-FOB) in the Fars salient (Fig. 3). To evaluate the possible stress variations along the trend of the orogeny from the northwest to the southeast, the study area extends from the Kazerun to Sarvestan fault zones (Fig. 3).
Tectonic and seismotectonic settings
The Zagros orogenic belt is the result of still continuing continent–continent collision between the Iranian microcontinent and the Afro–Arabian continent which probably started in the Late Cretaceous and developed during the Miocene–Pliocene times (Falcon 1974; Berberian and King 1981; Alavi 1994; Molinaro et al. 2005; Lacombe et al. 2006; Aubourg et al. 2010). The convergence of the Afro–Arabian continent with the Iranian microcontinent trends N–S to NNE, with a convergence velocity ranging from 23 (Bayer et al. 2003) to 35 mm year−1 (DeMets et al. 1990) (Fig. 2). The NE-trending shortening rate increases from the northwest to the southeast, up to approximately 10 mm year−1 (Tatar et al. 2002; Vernant et al. 2004). Some active transverse or cross faults within the Zagros orogenic belt, such as the Kazerun, Kar-e-Bass, Sabz-Pushan, and Sarvestan faults, trend nearly north–south, at a high angle to the structural trend of the orogenic belt, whereas other faults, such as the high Zagros and mountain front faults, trend NW–SE, sub-parallel to the belt. Right-lateral strike–slip faults cut across the trend of the belt and terminate as thrusts parallel to the folds (Figs. 2, 3). Folding, thrusting, and large-scale strike–slip transfer faulting is ongoing and seismicity is high in the area. The strike–slip faulting in the Zagros orogenic belt is comparable with such faulting from other collisional orogeny such as Himalaya (Mukherjee 2013, 2015a).
The high Zagros thrust fault divides the Zagros orogenic belt into two major belt-parallel structural zones known as the imbricated belt or high Zagros thrust belt in the northeast and the folded or simply folded belt in the southwest (Sepehr and Cosgrove 2005) (Fig. 3). Thrust faults and folds characterize the imbricated belt, whereas the simply folded belt has large, NW–SE-wards elongate anticlines. The mountain front fault subdivides the Foreland Folded Belt and has had a major role in controlling the sedimentation in the Zagros foreland basin since the early tertiary (Sepehr and Cosgrove 2004; Sherkati and Letouzey 2004). Based on the structural style and sedimentary history (Stöcklin 1968, 1974; Falcon 1974; Berberian and King 1981; Motiei 1993), the belt can be laterally divided into different zones: towards E—the Lurestan salient, the Dezful embayment, and the Fars salient (Sepehr and Cosgrove 2005; Lacombe et al. 2006) (Fig. 3).
As some authors (e.g., Sepehr and Cosgrove 2005; Burberry et al. 2011) suggested, Kazerun and Izeh faults are two pre-collisional faults in the Zagros orogenic belt that were initiated in the early Paleozoic as the extensional fault. It is suggested that during the early stages of plate collision (probably in oligocene, Aubourg et al. 2010), a gentle NW–SE trending within the Kazerun fault was initiated, and afterwards, this fault was reactivated as the segmented strike–slip and thrust fault. These lateral fault zones through the Zagros orogenic belt play a major kinematic role by accommodating the change in shortening, which is partitioned in the western central Zagros and non-partitioned in the eastern Zagros (Yamini-Fard et al. 2006, 2007). In the western central Zagros, the Afro–Arabia–Eurasia convergence is currently partitioned into NE–SW shortening that is perpendicular to the belt and right-lateral strike–slip faulting along the main recent fault (MRF) (Figs. 2, 3). In contrast, deformation in the eastern Zagros (Fars salient) is perpendicular to the local nearly E–W trends of the belt (Talebian and Jackson 2004). This kinematic change requires extension along the strike of the belt, which is accommodated along the Kazerun–Borazjan, Kar-e-Bass, Sabz-Pushan, and Sarvestan faults (Talebian and Jackson 2004), which form a horsetail system that transfers and distributes orogen-parallel dextral slip along the MRF onto the thrusts and folds of the Zagros orogenic belt (Authemayou et al. 2005; Lacombe et al. 2006).
Sarkarinejad and Azizi (2008) divided the Zagros orogenic belt into seven major sub-parallel tectonic elements: 1—the Zagros simply folded belt; 2—the Zagros fold-and-thrust belt; 3—the Zagros thrust system (ZTS); 4—Zagros suture zone/ophiolite zone; 5—the Sanandaj–Sirjan HP–LT metamorphic belt; 6—the Sanandaj–Sirjan HT–LP metamorphic belt; and 7—the Urumieh–Dokhtar magmatic belt. Sarkarinejad and Ghanbarian (2014) introduced new terminology that relates to orogenic belt and the Zagros hinterland fold-and-thrust belt (H-FATB). They suggested that the Zagros orogenic belt could be divided into seven major belts. In this paper, we modified these divisions and introduce the new division that divides Zagros orogenic belt into nine sub-parallel tectonic belts; these include from SW to NE: 1—Zagros Foreland Folded Belt; 2—Zagros foreland fold-and-thrust belt; 3—Zagros thrust system; 4—Zagros suture zone/ophiolite zone; 5—slate belt; 6—Zagros hinterland fold-and-thrust belt; 7—Sanandaj–Sirjan HP–LT metamorphic belt; 8—HT–LP metamorphic belt; and 9—Urumieh–Dokhtar magmatic belt (Fig. 4).
From the Cambrian to the Early Cretaceous, the Zagros orogenic belt experienced a long period of relatively stable platform sedimentation (Stampfli and Borel 2002; Sepehr and Cosgrove 2005). After the convergence began in probably the Late Cretaceous, the Pabdeh neritic marls and shale deposited in the Fars area. During the oligocene, Asmari massive shallow marine carbonates were deposited above the Pabdeh formation in the southwest, and the Jahrom formation was unconformably deposited in the northeast. From the Miocene to the Pliocene, the Fars group (which includes the Gachsaran, Mishan, and Agha Jari formation) deposited over the Asmari formation. These formations reflect the progressive infilling of the Zagros foreland basin (Lacombe et al. 2006) (Fig. 5). During the Pliocene, the continental Bakhtiari conglomerates represent the last main stage of sedimentation and are conformable along the Zagros front, but are unconformable in other parts of the belt to the northeast (Falcon 1961; Hessami et al. 2001; Homke et al. 2004) (Fig. 5).
The infra-Cambrian Hormuz salt in the Fars area lies on top of the basement and served as the major décollement horizon during the Late Tertiary deformation. Other décollement horizons include the Triassic Dashtak formation (evaporites), the Cretaceous Kazhdumi formation (shale), and the lower Miocene Gachsaran formation (evaporites) (Fig. 5). These décollement horizons decoupled deformation between the basement and sedimentary cover and also between different units within the sedimentary cover. These horizons control the pattern and distribution of deformation within the Zagros (O’brien 1950; Colman 1978; Letouzey and Sherkati 2004; Sepehr and Cosgrove 2004; Casciello et al. 2009; Farzipour-Saein et al. 2009). The GPS-derived velocity field and the seismicity record show decadal-scale quiescence across the higher elevation parts of the Zagros and confirm the absence of active upper crustal shortening within this region (Allen et al. 2013).
In the Zagros orogenic belt, the faults formed before, during, or after folding. Pre-folding faults include syn-sedimentary normal faults and small-scale thrusts (Casini et al. 2011; Lacombe et al. 2011). Thrust faults, that have the vergence to SW, developed during folding, and strike–slip faults typically postdate the pre- and syn-folding structures and probably relate to the later stages of fold tightening. The general chronology of the brittle tectonic events, with the corresponding σ 1 (maximum principal stress axis) trend within the Zagros, from previous studies (e.g., Navabpour et al. 2007 within the high Zagros belt in Fars Province) is NE–SW, NNE–SSW, NW–SE, and N–S. FL refers to the main stage of folding and related reverse structures, and it occurred between the NE and NNE events. The sequence of NE → FL → NNE → N indicates an anticlockwise rotation in the compression direction over time. Due to the lack of a sufficient number of compatible chronologies, Navabpour et al. (2007) noted that the geochronology of the NW event is not reliably constrained with respect to the other events.
The seismicity in the Zagros orogenic belt is limited to the region between the Persian Gulf coastal plain and the Zagros thrust system (Fig. 6). The abundance of earthquakes in this region indicates that the area is actively deforming, a kind of out-of-sequence deformation that has also been noted from similar collisional orogeny (e.g., Mukherjee et al. 2012). The larger magnitude earthquakes (M b > 5) are concentrated in the Zagros Foreland Folded Belt, an area of low topography (<1500–2000 m; Jackson and McKenzie 1984; Ni and Barazangi 1986; Talebian and Jackson 2004; Hatzfeld et al. 2010). Tatar et al. (2004) and Hatzfeld et al. (2010) infer that the seismicity in the central Zagros is beneath the sedimentary cover and within the upper part of the basement (between ~10 and ~15 km depth) (Figs. 7, 8). These earthquakes are not located on the main faults, as observed at the surface, but instead are spread over more distributed areas (Hatzfeld et al. 2010). Furthermore, the presence of Hormuz salt at the base of the ~10 km-thick folded sedimentary cover, together with the general absence of coseismic surface rupturing, indicates that earthquakes are concentrated within the basement (Nissen et al. 2011).
Catalogues of earthquakes determined earthquake locations in this region with uncertainties of up to 50 km in map view (Maggi et al. 2000; Ambraseys 2001; Talebian and Jackson 2004; Lohman and Simons 2005).
Yamini-Fard et al. (2006, 2007) analyzed the focal mechanisms and found that at the intersection between the Kazerun fault and the MRF in Borujen, as well as at the transition between the Zagros collision zone and the Makran subduction zone near Bandar Abbas, the thrust focal mechanisms are confined to depths >~12 km along NE-dipping décollement faults that strike perpendicular to the convergence direction. In contrast, dextral strike–slip focal mechanisms are recorded at shallower depths under the trace of the MRF. This difference in the depth of the focal mechanisms suggests that the upper crust deforms mostly by slip on weak, pre-existing faults, either strike–slip or thrust, but that the lower crust is more homogeneous and accommodates shortening by reverse faulting perpendicular to the regional motion (Hatzfeld et al. 2010). Most of the earthquakes in the study area are compressional dip–slip and strike–slip, with epicenters at depths between ~10 and ~20 km (Figs. 7, 8).
Inversion of earthquake focal mechanism and fault–slip data
To reconstruct the paleo and recent stress states within the study area, we applied two methods: (1) inversion of the earthquake focal mechanisms and (2) inversion of fault–slip data.
To determine the present-day stress pattern in the western Fars, we used inversion of the earthquake focal mechanisms described by previous studies (McKenzie 1969; Otsubo et al. 2008; Yamaji et al. 2011). Fault–slip analyses and paleo-stress methods are commonly applied to infer different phases of extension and shortening (Angelier 1990; Zalohar and Vrabec 2007). We applied inversion of the slickenlines on fault planes (Mukherjee 2014, 2015b; Kaplay et al. 2017; Misra and Mukherjee 2017; Dasgupta and Mukherjee 2017) to constrain the stresses responsible for older phases of deformation. Both these methods are based on the Wallace–Bott hypothesis that expresses the slip vector of an earthquake as parallel to the resolved shear stress on the fault (Wallace 1951; Bott 1959).
Earthquake focal mechanism inversion method
The multiple inverse method (MIM) (Yamaji et al. 2011) is a numerical technique for determining the stress directions from the earthquake focal mechanism data. This method does not require a fault plane from the two nodal planes (Yamaji 2000b; Otsubo et al. 2008; Yamaji et al. 2011), because it assumes that both the nodal planes acted as the fault planes. On Mohr diagrams (Fig. 9), normal and shear stresses are normalized with values of 0–1 and 0–0.5, respectively. The resulting principal stresses are represented as clusters of reduced stress tensors (Otsubo et al. 2006, 2008). A reduced stress tensor represents the stress tensors that have ordinary principal orientations and a Φ value. If the fault attitudes and magnitude and direction of the normal and shear stress are known, the MIM software can calculate the misfit angles between the observed and theoretical fault–slip directions (Fig. 9) and minimize the sum of the misfit angles (Otsubo et al. 2008).
The MIM method has been used throughout the study area to determine the state of stress using available focal mechanisms. Because of the heterogeneity of the focal mechanism data, the study area was subdivided into five domains, where the state of stress is nearly homogeneous (Fig. 8). The results of orientations of the maximum and minimum principal stresses could be shown as clusters of points on the unit sphere for all earthquake focal mechanisms (Fig. 10). The clusters are identified using the k-means clustering algorithm (Otsubo et al. 2006). The tangent-lineation diagrams (Fig. 11) show the theoretical slip directions for the state of stress and the computed slip directions derived from inversions of the earthquake focal mechanisms.
The focal mechanism catalogue contains events with a moment magnitude M w > 4.2, as reported by the Global Centroid Moment Tensor (GCMT) and the Zurich Moment Tensors (ZUR_RMT), for the period between 1976 and 2012 (Table 1). The data include the focal location, earthquake date and time, depth and magnitude of the earthquakes, the strike and dip of the nodal planes, the rake of the hanging-wall’s slip direction, the fault mechanism, and the centers that reported the earthquakes (Table 1).
The data set contains 58 focal mechanisms: compressional dip–slip (~50%), extensional dip–slip (~3%), oblique–slip (~9%), and strike–slip (~38%) mechanisms (Fig. 8). The study area is subdivided into five domains that include the five major fault zones (Kazerun, Kar-e-Bass, Sabz-Pushan, Sarvestan, and Ghir fault zones) (Fig. 8). In each fault zone, the focal mechanisms of the earthquakes have been extracted to reveal the present-day stress regime.
In the Zagros Foreland Folded Belt (F-FOB) and Zagros foreland fold-and-thrust belt (F-FATB), the earthquake locations are not sufficiently accurate to justify linking seismic events to specific faults or to obtain precise focal depths because of the sparse seismic network and absence of an accurate crustal velocity model. On the other hand, the accuracy of the earthquake locations is approximately 20 km (Engdahl et al. 1998; Hatzfeld et al. 2010). Based on this deficiency, we have allocated a wide area (~15′ or ~30 km wide) around each fault zone (Fig. 8).
To infer the present-day state of stress in the Fars salient, we applied the stress inversion method to the focal mechanism data. The data are the azimuth and dip of two nodal planes and the rake of the lineations. The stress inversion methods assume a uniform state of stress. To interpolate the P- and T-axes (approximations of maximum and minimum principal stress directions), the method yields the principal stress axes and ratio between the principal stress magnitudes. The misfit angle is the angle between the measured slickenlines and the calculated relative shear stress, τ. Following the MIM (Yamaji et al. 2011), the ellipsoid has axes that are parallel to the principal stress axes and radii X, Y, and Z (with X ≥ Y ≥ Z), satisfying the relation that (Y–Z)/(X–Z) equals the Φ value of the stress state (Table 2). Shape ratio Φ has a value between 0 and 1; Φ = 0 for a prolate stress ellipsoid, where σ 2 = σ 3 (uniaxial compression); Φ = 1 implies that the stress ellipsoid is oblate and σ 1 = σ 2, (uniaxial tension) (Fossen 2016).
Fault–slip inversion method
Study of the paleo-stress field helps us for better understanding deformation of orogenic belts and the migration of hydrocarbon and/or hydrothermal fluids. The kinematics of a fault zone are defined using slickenlines that were produced by a few millimeters to several meters of movement along a fault plane. For each fault, the strike and dip of fault plane, the rake orientation of lineation, and the sense of movement were measured in the field and recorded (Fig. 12). These data are the results of many measurements over the large areas around each fault. To infer the stress state that is responsible for the deformation in the study area, we inverted distinct groups of slip data measured at individual sites using the Gauss method (T-Tecto software) of Zalohar and Vrabec (2007).
The fault–slip inversion method assumes that (1) the rock body is mechanically homogeneous and isotropic; (2) the rock has a linear viscous rheology (Twiss and Unruh 1998; Lacombe 2012); (3) displacements on the fault planes are small with respect to their lengths and there is no ductile deformation and, thus, no rotation of the fault planes; (4) a tectonic event is characterized by a single homogeneous stress tensor; (5) the fault plane is a pre-existing fracture and the slip responsible for the slickenlines occurs in the direction of maximum resolved shear stress; and (6) the slip on each fault plane is independent of the slip on all other fault planes. Some authors (e.g., Twiss and Unruh 1998) claim that because of the different orientations of the stresses inside and outside the fault zone, the linearity and isotropy behavior of the fault zone cannot be used as an assumption for inferring the stress from inversion of fault–slip data. They also mention that the degree of inaccuracy would depend on the degrees of anisotropy and non-linearity, which at present remain unknown. However, at the regional scale, the stress field can be analyzed in the region that be divided into smaller more homogeneous sub-domains which has much more isotropy and linearity. As a result, it is reasonable to compare results of inversion of fault–slip data with contemporary stresses (e.g., the stress derived from earthquake focal mechanisms), and try to combine both results to better understand the mechanical behavior of the continental crust (Lacombe 2012).
The basic principle involves finding the best fit between the observed directions and senses of slip on the numerous faults and theoretical shear stress on these planes. Similar to the inversion of the earthquake focal mechanisms, the results are reported as the trend and plunge of the three principal stress axes, σ 1, σ 2, and σ 3, and the ratio \(\varPhi = (\sigma_{2} - \sigma_{3} )/(\sigma_{1} - \sigma_{3} )\), which describes the shape of the stress ellipsoid, and thus, the nature of the stress regime (for example, if \(\sigma_{3}\) is vertical and Φ close to 0, it indicates a reverse/strike–slip regime) (Bott’s 1959; Fossen 2016). Numerical estimators, such as the average misfit angle between the computed shear stresses and the actual slickenlines on fault planes, record the validity of the calculated tensor. The absolute values of the stress components cannot be determined, but the optimal principal orientations and stress ratio are obtained using Gauss-inverse method. Unlike the results obtained from the inversion of the focal mechanism, the results of the fault–slip data refer to deformation within the sedimentary cover.
If the observed tilted bedding is a result of folding, the faults in that region may have formed before, during, or after folding. In the case where faults formed before folding, the striations should be back rotated before analysis and interpretation (Lacombe et al. 2006). Anderson (1951) suggested that one of the three principal stress axes is generally vertical (or horizontal) in major fault zones, but the slight departures from this rule (<10°, that have been seen in some of our measurements) are common (McGarr and Gay 1978). If a fault was active before folding and was subsequently passively tilted with the bedding, the stress tensor calculated on these data does not have a vertical (or horizontal) axis. Instead, one of the stress axes is generally perpendicular to the bedding, whereas the two other stress axes are along the bedding plane. In these cases, the fault system should be analyzed after back tilting to its initial position (Lacombe et al. 2006). Accordingly, sites 9 and 10 within the Sarvestan fault zone and sites 11, 12, and 13 within the Ghir fault zone were back tilted before interpretation (Fig. 13).
Age estimation for fault–slip formations
Some authors (e.g., Angelier 1991; Yamaji et al. 2005; Lacombe et al. 2006; Navabpour et al. 2007; Sperner and Zweigel 2010) believe that the relative age of the fault–slip events can be estimated based on: (1) the recognized sequences of faulting and folding, the chronology of two superposed and differently oriented fiber lines on a fault plane; (2) the ages of deformed units of known stratigraphy; and (3) the horizontal axis rotations of the stratigraphy from folding. Furthermore, at locations with significant layer tilting, brittle events must be dated with reference to the folding. On other hand, some authors (e.g., Hippolyte et al. 2012) note that these methods of estimating the timing of fault–slip are often difficult to determine with confidence. The inversion of the fault–slip data results in a mean stress tensor that is averaged over time (several thousands or millions of years) and space (the volume of rock containing the analyzed faults), and without an exact dating method, the actual time of faulting cannot be well constrained. In our study, we do not have a way to determine the exact age of the slickenlines. However, we have assumed that the age of the slip events on the faults is confined between the depositional ages of the faulted rocks and the present. In the case where the striations formed before folding (within the Sarvestan and Ghir fault zones), the age of the slickenlines is interpreted as older than initial fold development. At other sites, the age of the stress state places the event after folding. In general, we know that the stress regimes obtained from the focal mechanism inversion are definitely younger than the stress regimes obtained from inversion of the fault–slip data.
Results of stress analyses
Earthquake focal mechanism inversion
Because earthquakes with higher magnitudes yield more accurate nodal plane locations and geometries (e.g., Hatzfeld 1999; Maggi et al. 2002), we have used earthquakes with moment magnitudes M w ≥ 4.2 in our analysis. Most of the thrust earthquakes (between 1968 and 2000, Talebian and Jackson 2004) occur along the SW Zagros margin, between the coastal plain of the Persian Gulf and the Surmeh–Ghir thrust system, while the strike–slip earthquakes are closely associated with the Kar-e-Bass and Sabz-Pushan fault zones (Fig. 6; Lacombe et al. 2006). The Kazerun fault zone has both compressional dip–slip and strike–slip motions, and the Ghir fault zone is dominantly compressional dip–slip (Fig. 8).
Because the seismicity in the central Zagros is beneath the sedimentary cover and in the upper part of the basement (Tatar et al. 2004; Hatzfeld et al. 2010), the results obtained from inversion of the focal mechanism refer to the foreland gneissic basement.
Kazerun fault zone
Among the 58 earthquakes focal mechanisms (recorded from 1976 to 2012), 33 occurred within the Kazerun fault zone (latitude 29°–30.5°; longitude 51°–52°, Table 1).
For the Kazerun fault, the trend and plunge of σ 1 and σ 3 are S46°W′09° and N42°W′09°, respectively, and the stress ratio Φ = 0.04. These results indicate a strike–slip faulting regime with NE–SW compression and NW–SE tension (Table 2; Fig. 14).
Kar-e-Bass fault zone
Seven focal mechanisms from the earthquakes (latitude 28.5°–29.5°; longitude 52°–52.5°) within the Kar-e-Bass fault were analyzed.
For the Kar-e-Bass fault zone, the trend and plunge of σ 1 and σ 3 are N26°E′08° and N65°W′08°, respectively, and the stress ratio is Φ = 0.72. These results also indicate a strike–slip faulting regime with NE–SW compression and NW–SE tension (Table 2; Fig. 14).
Sabz-Pushan fault zone
Five focal mechanisms from earthquakes with latitudes between 28.5° and 29.5° and longitudes between 52.5° and 53° within the Sabz-Pushan fault zone reveal the orientations of σ 1 and σ 3 to be N00°E′08° and S88°E′08°, respectively, and that the stress ratio Φ is equal to 0.6. These results indicate a strike–slip faulting regime with N–S compression and E–W tension (Table 2; Fig. 14).
Ghir fault zone
An analysis of 13 focal mechanisms from earthquakes with latitudes between 28.5° and 29.5° and longitudes between 52° and 52.5° within the Ghir fault zone reveal the σ 1 and σ 3 orientations to be N05°E′04° and S63°W′83°, respectively, and the stress ratio to be 0.88. This solution indicates a thrust faulting regime with N–S compression and NE–SW tension (Table 2; Fig. 14).
Fault–slip inversion
To evaluate the paleo-stress regime of the Kazerun, Kar-e-Bass, Sabz-Pushan, Sarvestan, and Ghir fault zones, we defined suitable sites along each fault and measured the strike and dip of the fault plane, rake of the slickenline, and polarity of movement for each one in the field. For more accuracy, all measurements have been done with Brunton compass. In each fault zone, the number of sites and measurements is shown in Table 3. According to field observations and Anderson (1951), the fault systems in sites 10 and 11 in the Sarvestan fault zone and sites 12, 13, and 14 in the Ghir fault zone were back tilted prior to interpretation and analysis (Fig. 13; Table 3). The attitude (strike and dip) of the tilted beds belong to Sarvestan and Ghir faults are S70°W′30°NW and S75°E′30°SW, respectively. For back tilting, the tilted layer was rotated on equal-area or equal-angle stereonets to be horizontal; the related faults were rotated as the same angle and direction.
Varied stress regimes are specified by different orientations of the principal stress axes. The inversion of the fault–slip data for the study area revealed stress regimes varying from compressional to tensional dip–slip and strike–slip for the Kazerun, Kar-e-Bass, Sabz-Pushan, Sarvestan, and Ghir fault zones. Table 3 and Figs. 15, 16 show the results of the analysis for each fault zone in the study area. As shown in Fig. 15, most sites have NE–SW compression, consistent with the convergence between the Afro–Arabian and Eurasian continent. The middle segment of the Kar-e-Bass fault zone (site 07) indicates the compressional trends ~130° and is incompatible with the compression direction measured in other fault zones. All the data have been measured from three major formations that have different ages. The compressional trend is slightly different in different formations (Tables 3, 4). Although the time of sedimentation has been known, without an exact dating method, the actual time of faulting cannot be well constrained (see “Age estimation for fault–slip formations”).
Discussion
The stress regimes obtained by inverting the fault–slip data may be local or regional. Only results that are consistent throughout the entire area can be considered tectonic regimes (Lacombe et al. 2006). Thus, the results obtained from the sites with a small spread of slickenlines have been eliminated. In each fault zone (Kazerun, Kar-e-Bass, Sabz-Pushan, Sarvestan, and Ghir fault zones), the inversion of both the earthquake focal mechanisms and fault–slip data provides information regarding the temporal and spatial changes in the tectonic stress regime in the study area (Tables 2, 3). These results allow us to illustrate changes in the direction of the principal compressional stress from the older deformation to the most recent deformation (Figs. 14, 15). The inversion of the earthquake focal mechanisms shows that the present-day compressional direction averages ~N19°E and is compatible with the general direction of the recent convergence between the Afro–Arabian and Eurasian continents (~N13°E at the longitude of 52°E, Vernant et al. 2004). From NW to SE (from Kazerun to Ghir fault zone), the spatial variation in the recent compressional trend has a counterclockwise rotation. This rotation is consistent with the spatial change of the Afro–Arabian–Eurasian convergence paths along the Zagros orogenic belt that has been previously suggested (e.g., Vernant et al. 2004; Walpersdorf et al. 2006).
On the other hand, the fault–slip data produce an average trend of ~N38°E for the paleo-compression direction. These results are consistent with the results of stereographic projection of the folds within the study area (Fig. 17). The major fold axial planes are good kinematic indicators to estimate the compressional trend (Ramsay and Huber 1987; Doblas 1998).
The relative consistency of the results from the inversion of the focal mechanisms and the fault–slip data also suggests that there is not a significant temporal variation in the direction of compression from Tertiary to recent time in the study area, although there is an anticlockwise rotation of the compression through time (over ~56 Ma, Fig. 1). Fault–slip date inversion also shows an anticlockwise change of the compression from upper Cretaceous to Oligocene (Table 4). In upper Cretaceous, the compressional direction is NE–SW, while in Oligocene, it has rotated towards N. Although without the exact dating method, the actual time of faulting cannot be well constrained.
Inversion according to reconstructions of the long-term Afro–Arabian–Eurasian convergence paths (McQuarrie et al. 2003), the relative plate motion changed from N30°E (56–33 Ma) to N25°E (33–19 Ma), N09°E (19–10 Ma), and N05°E (last 10 Ma) (Fig. 1). Navabpour et al. (2007) used these results to suggest that the change in the convergence path over time presumably caused the change in the compressional directions. However, Lacombe et al. (2006) assert that the temporal change in the compressional trend obtained from tectonic analyses cannot be related to a change in plate kinematics over such a relatively short time span. They believe that it is more likely to reflect the local structural evolution of the Zagros orogenic belt within the framework of the Afro–Arabian–Eurasian continental convergence. We suggest that the variation in the compressional trend over time resulted from changes in the continental convergence path, but that it was also influenced by the local structural evolution, such as lateral propagation folds and the presence of several décollement horizons that allowed decoupling of deformation between the basement and the sedimentary cover (Oveisi et al. 2007).
Because the results that we have obtained from the inversion of the earthquake focal mechanism and the fault–slip data are from the foreland gneissic basement and sedimentary cover, respectively, the relative consistency between the results suggests that the compression has little inhomogeneity in both the overburden and the basement. Consequently, there are few changes in the compressional trend between the upper crust and the ductile Hormuz salt décollement horizon. A comparison between the GPS surface displacement (Vernant et al. 2004; Tavakoli et al. 2008) with the early Pliocene compression in the Fars area (~5 Ma) supports this suggestion.
The lateral ramps and segmented strike–slip/dip–slip fault zones
Unlike the locations of the studies by Lacombe et al. (2006) and Navabpour et al. (2007), the locations chosen in our study were close to fault zones. The compatibility of our results with those of Lacombe et al. (2006) and Navabpour et al. (2007) (Fig. 18) indicates that, in the vicinity of the main lateral fault zones, the stress regime is similar to that in other parts of the Zagros orogenic belt. On the other hand, three lateral fault zones (Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones) as well as the Ghir thrust fault on both sides indicate an NNE–SSW compressional trend (the Kazerun fault indicates NE–SW compressional direction). The lateral faults are characterized by structures oblique to the belt. As Cotton and Koyi (2000) suggested from the results of sandbox modeling experiments, the development of transverse structures in response to a lateral change in the overburden thickness due to the basement geometry or a basin boundary or to the lateral termination of the main décollement horizon may occur in a thrust sheet moving over a décollement level. The consistency between the compressional trend of the Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones on both sides (previous studies, such as those of Lacombe et al. 2006; Navabpour et al. 2007) and also the homogeneity of structural style of deformation on both sides of them, indicates that these fault zones may have initiated as primary tear faults in the sedimentary cover above the décollement horizon that formed in response to a lateral change in the cover thicknesses due to half graben inversion of the foreland gneissic basement. The temporal change in the compressional trend from NE–SW to NNE–SSW and/or block rotations is caused by change in behavior of the Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones from tear faulting to strike–slip faulting. This change could be coeval with the onset of the main phase of basement-involved shortening (Lacombe et al. 2006). The strike–slip and dip–slip-type basement earthquake events along the Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones and the related apparent lateral offsets of folds in both basement and sedimentary cover (Berberian 1995; Lacombe et al. 2006) suggest that in recent times, these fault zones acted as segmented strike–slip and dip–slip faults in both the basement and the sedimentary cover. The obliquity of the maximum compressional stress into the fault trends reveals a typical stress partitioning of strike–slip and thrust motions in the Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones. The field evidences and seismic data support this suggestion that the Kar-e-Bass (Sarkarinejad and Zafarmand 2017b), Sabz-Pushan, and Sarvestan fault zones behave as segmented strike–slip and dip–slip faults.
Deep-seated earthquakes in vicinity of the Kazerun fault (Fig. 8), together with differences about 20°–30° in compressional trend between the Kazerun fault and other fault zones and also different structural style on both sides of Kazerun fault zone (Fars salient and Dezful embayment), show that Kazerun fault is a basement fault that it is infrastructure probably be different with other lateral fault zones within the study area (Kar-e-Bass, Sabz-Pushan, and Sarvestan). Some authors (e.g., Sepehr and Cosgrove 2005; Burberry et al. 2011) suggested that Kazerun fault is one of the pre-collisional fault in the Zagros orogenic belt that was initiated in the Early Paleozoic as the extensional faulting. Therefore, we suggest that during early stages of continental collision, a gentle NW–SE trending within the Kazerun fault was initiated, and afterwards, this fault was reactivated as the segmented strike–slip and dip–slip fault. These reactivated segmented faults related to the asymmetrical half grabens are shown as double arrows in the crustal-scale Zagros orogenic belt (Fig. 4). Just like the other lateral faults (Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones), in the Kazerun fault zone, the obliquity of the maximum principal stress to the fault trend caused typical stress partitioning of dip–slip and strike–slip motion that led the Kazerun fault behaves as segmented dip–slip and strike–slip fault. The activities of the Zagros orogenic belt during transmission of collision-related compressional stress (Coward 1983; Ziegler et al. 2002) into the foreland strongly related either to the deep-seated basement inverted faults underlies the sedimentary cover or gently dipping shallow-seated décollement horizon of the rheological weak rocks of the infra-Cambrian Hormuz salt.
Recent-aseismic Sarvestan fault zone
Field evidence of the slickenlines on the fault planes suggests that the faults in the study area were active before quaternary (Tables 3, 4) and that there has not been a significant change during the quaternary. However, in recent times, the number of earthquakes decreases from the Kazerun to the Sarvestan fault zones, with no seismic activity on the Sarvestan fault (Fig. 8; Berberian 1995 suggested that no direct seismic evidence has been found along the Sarvestan fault). Allen et al. (2013) suggested that the seismicity of the Zagros orogenic belt is influenced by the changes in elevation. Because the Kazerun, Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones are in the same structural zone (F-FOB) of the Zagros orogenic belt and there is not a large elevation difference between them, the effect of elevation on the reduction in seismicity along the Kazerun to Sarvestan faults is invalid. Two possible scenarios may explain the seismicity reduction between the Kazerun to Sarvestan fault zones: (1) tectonic shear stress variations from the Kazerun to Sarvestan fault zones and (2) locking along the Sarvestan fault. In support of 1, it seems that, presently, horizontal stress partitioning occurs, resulting in a higher resolved shear stress on the Kazerun and Kar-e-Bass faults, but less on the Sarvestan fault. In scenario 2, the Sarvestan fault may be currently locked due to the fault geometry or high friction; if so, there are consequences for seismic hazard assessments.
The NW–SE compressional regime
In the middle segment of the Kar-e-Bass fault zone (site 7), the NW–SE direction of compression is significantly different from the compression direction at the other sites. Lacombe et al. (2006) and Navabpour et al. (2007) also reported this inconsistency between different locations (especially between the Kar-e-Bass and Sabz-Pushan fault zones). In our opinion, three probable scenarios are reasonable. First, the sites that have a compression direction of approximately 130° are in the vicinity of salt diapirs, and the rheological contrast between the salt and the sediment may have affected the local stress distribution. Second, as per Berberian (1995), this site is located on a part of the Kar-e-Bass fault that bends and acts as a transfer fault, and the dextral sense of shear on the fault may create a trans-tension zone. Third, a northwest compressional event might have occurred in the Pliocene after the main phase of folding in the Zagros orogenic belt. However, as noted by some authors (e.g., Navabpour et al. 2007), the NW event is not reliably constrained relative to the other events. We suppose that the NW event is a real and significant event that occurred after folding. If so, the idea of anticlockwise rotation of the compressional trend through time is invalid.
Conclusions
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The compressional regimes obtained from the inversion of the fault–slip data and the earthquake focal mechanisms are mutually consistent with the convergence between the Afro–Arabian continent and the Eurasian continent.
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In the study area within the Zagros Foreland Folded Belt (F-FOB), a comparison between the paleo-compression directions obtained from fault–slip data and recent compression directions obtained from earthquake focal mechanisms indicate that there was insignificant variation in the compression direction throughout time. However, an anticlockwise rotation in the direction of the principal compressional stress over time is compatible with the variation of Afro–Arabian and Eurasian continental collision paths. However, the NW compression direction observed in the middle segment of the Kar-e-Bass fault is incompatible with an anticlockwise rotation.
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The compatibility of our results with those of Lacombe et al. (2006) and Navabpour et al. (2007) (Fig. 18) indicates that there is not a significant difference in the compression direction in the vicinity of the lateral fault zones compared to the other parts of the Zagros orogenic belt. Consequently, the lateral fault zones (Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones) may have initiated as tear faults in the cover above the décollement horizon along the thrust (e.g., HZF and MFF), and in recent times, these fault zones act as strike–slip/dip–slip faults in both the basement and the sedimentary cover.
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The obliquity of the maximum principal stress into the fault trends reveals a typical stress partitioning of dip–slip and strike–slip motions in the Kazerun, Kar-e-Bass, Sabz-Pushan, and Sarvestan fault zones that caused these fault zones behave as segmented strike–slip/dip–slip faults.
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The almost relative consistency in the compressional direction in both the sedimentary cover and the gneissic basement suggests that there is no significant change in the crustal compressional trend between basement and cover.
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There are two sources of the fault activities either as pre-existing dip-seated reactivated faults or as shallow-seated faults of the decoupling or décollement of rheological weak evaporates in the study area.
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Acknowledgements
The authors wish to thank Dr. Soumyajit Mukherjee, Editor of International Journal of Earth Sciences, the anonymous reviewers for valuable comments and suggestions that helped for improvement of the manuscript. Thanks Mr. Pejman Vaghari for his friendly help in field work. This research was supported by the Shiraz University Research Council (SURC) grant which is gratefully acknowledged.
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Sarkarinejad, K., Zafarmand, B. & Oveisi, B. Evolution of the stress fields in the Zagros Foreland Folded Belt using focal mechanisms and kinematic analyses: the case of the Fars salient, Iran. Int J Earth Sci (Geol Rundsch) 107, 611–633 (2018). https://doi.org/10.1007/s00531-017-1516-3
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DOI: https://doi.org/10.1007/s00531-017-1516-3