Abstract
Anisotropy strength in the Tres Vírgenes Volcanic Complex, Baja California Sur, Mexico, is analyzed employing 558 seismic events collected from 2009 to 2013. It was possible to delineate zones and volumes with the highest fracture densities, which are mainly located between the El Viejo and El Azufre volcanoes and around the La Reforma–El Azufre fault system, near some other mapped faults in the area (e.g., El Azufre, El Partido, El Volcán, El Viejo 1, and El Viejo 2 faults); likewise toward the La Virgen volcano and around the La Virgen-El Campamento and El Volcán faults. Individual delay times reached values of up to 0.16 s and an anisotropy percentage of up to 10.3%, with a pervasive anisotropy observed from at least a hypocentral distance of 3.5 km. High fracturing levels are observed from a depth of 7.0 km. Differences between splitting delays and the dominant frequency peaks obtained from the fast S phases allowed considering fracture systems with different degrees of fluid contents. Fractures with minor fluid contents were assumed for delay times higher than 0.03 s with lower dominant frequency peaks (< 1.0 Hz). Higher concentrations of fluid inclusions were assumed for splitting delays higher than 0.03 s but with larger dominant frequency peaks (> 1.0 Hz). Fractures systems chemically sealed or impermeable sealing caps were assumed for low splitting delays (< 0.02 s) with low dominant frequencies (< 1.0 Hz). These different fracture systems seem to be observed at least from 5- to 6-km depth intervals. Likewise, an analysis of the fast polarization directions with respect to different depth ranges (spanning from 3.0 to 8.0 km) has allowed observations of a strong NW–SE regional fracture system accompanied by minor NE–SW fracture systems. However, noteworthy variations from NW–SE to NE–SW, N–S, and E–W in fast polarization directions in rose diagrams have been preferentially observed for those seismic events deeper than 4–5 and 5–6 km in some areas, which could be indicating the location of magmatic bodies that probably caused the reorientation on fracture systems by changes in the local stress field. These magmatic bodies might be supported by a decrease in the dominant frequency peaks (lower than 1.0 Hz), percentage of anisotropy (from 0.1 to 2.5%), and S-wave velocities (from 1.0 to 2.7 km/s), which seem to be located from the 4.0-km depth but more concentrated from the 5–6-km depth interval.
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Introduction
The shear-wave splitting phenomenon has been observed in many volcanic (e.g., Miller and Savage 2001; Roman et al. 2011; Baird et al. 2015) and geothermal areas (e.g., Zúñiga et al. 1995; Lou et al. 1997; Tang et al. 2005; Mroczek et al. 2020), whose corresponding studies have helped to show preferential structural alignments and fracture densities. The preferential structural alignments produce splitting of the shear wavefield into two orthogonally polarized phases with different velocities, the fast shear-wave phase S1 and the slow shear-wave phase S2, a phenomenon also known as seismic birefringence. In the case of crack-controlled anisotropy, S2 is perpendicular to the crack planes, while S1 is polarized parallel to the crack plane which tends to point along the orientation of the principal horizontal stresses. This parameter is also known as the fast polarization direction parameter ϕ. The difference in arrival time between both phases is proportional to the magnitude of anisotropy or the integrated effect of anisotropy along the travel path (Savage et al. 2010), which is known as the delay time parameter δt. The estimation of both birefringence parameters forms the basis of the shear-wave splitting technique (SWS). In this study, the anisotropy percentage is particularly assumed to be an indicator of fracturing.
Volcanic areas have been considered as strategic environments due to their energetic potential by hosting geothermal fluids, where fractured rock volumes constitute the main target in geothermal exploration. Within this context, a good structural characterization of volcanic areas represents a challenge since they represent complex systems, consisting of both heterogeneous and anisotropic structures that evolve. Usually, they are influenced and affected by phenomena and dynamic processes, such as migrations of magmatic bodies, dyke pressurization, hydrothermalism, or meteoric fluids, producing changes in the local stress fields with alterations in the anisotropy strength (Baird et al. 2015). Furthermore, geothermal energy operations add an effect generated by injection/production activities that might enhance or affect the interaction between deeper or shallower crack systems, modifying the internal geometry (Sayers and Schutjens 2007) with cracks opening and closing (Mroczek et al. 2020). Usually, geothermal operations generate deformation mechanisms, cement breakage at grain contacts, grain sliding, and rotation (Schutjens et al. 2004), with tension and compression changes in the surrounding rock connected to the reservoir (Sayers and Schutjens 2007). These mechanisms lead to a combination of elastic and inelastic deformation processes (Sayers and Schutjens 2007) with changes in the rock volume by the flow rate out of or into the reservoir (Vasco et al. 2008). As a part of these geothermal operations, seismicity has been observed with time delays (Tosha et al. 1998), located far away (McGarr et al. 2002; Ellsworth 2013) and at greater depths of the injection zone, due to readjustment of the surrounding internal structures (Rubinstein and Mahani 2015).
These variations in space and time of seismic events have influenced the results of the ϕ and δt parameters (Johnson et al. 2011; Chacón-Hernández et al. 2021a), especially when several anisotropic sources contribute to the overall anisotropy. For example, crystals and mineral alignments (inherent properties of the rocks) can differ from a specific orientation of a fracture system (Kendall et al. 2007) or from the orientations of a group of fracture systems (Liu et al. 1993; Erten et al. 2001). Similarly, some processes occurring in volcanic and geothermal environments, such as changes in pore-fluid pressure by injection procedures (Angerer et al. 2002) or by movement of magmatic bodies (Baird et al. 2015; Maher and Kendall 2018), could complicate the anisotropic analysis due to modifications in the geological structures. Likewise, hydrothermal systems can modify the rock volume (Teklemariam et al. 1996) and deform volcanic structures (e.g., at Aluto volcano, Nowacki et al. 2018). To avoid as much as possible anisotropic sources that could affect the anisotropic measurement, seismic information from a more restricted area can be considered to obtain an anisotropic signal freer from some influences and effects. For example, Gledhill et al. (1991) correlated local faults with more stable fast polarization directions when the analysis was limited to a minor area, in contrast to what was observed at other stations when data from a broader zone were included. When a broader area is analyzed, the birefringence parameters may show more regional influences, with a mean fast polarization direction parallel or sub-parallel to the maximum compression direction [e.g., Las Tres Vírgenes Volcanic Complex, Chacón-Hernández et al. 2021b], but also perpendicular [e.g., Mount Ruapehu, Miller and Savage 2001; Los Humeros Geothermal Field Chacón-Hernández et al. 2021a].
Different behaviors between the birefringence parameters (ϕ and δt), seismic wave velocities, and seismic frequency ranges have allowed studying those phenomena and dynamic processes mentioned above. For instance, when a medium contains fractures as main anisotropic structure, the anisotropy tends to become dependent on seismic frequency, with the fracture sizes (e.g., fracture connectivity) determining the behavior of this dependence (Rial et al. 2005) (e.g., the dominant frequencies drop for increases in δt or larger fracture sizes, Elkibbi 2004). From regional analyses, Marson-Pidgeon and Savage (1997) also observed a frequency-dependent anisotropy, with increasing δt values (from 1.0 to 4.0 s) for a lower dominant frequency range (from 0.05 to 0.2 Hz) and inversely. This shows how structural alignment influences seismic frequency ranges, but what happens if different types of fluids (e.g., vapor, liquid, magmatic, or mixtures of them) flow through these structures?
It has been observed that splitting times are induced by the different types of fluids and their contents, whose analysis is not always simple. In volcanic zones, increases in the percentage of anisotropy, as well as variations in ϕ and δt have been observed when geothermal procedures are carried out due to stimulation by hydraulic fracturing (e.g., Vlahovic et al. 2002; Rial et al. 2005; Mroczek et al. 2020). Gerst and Savage (2004) observed in a study of repressurization of magmatic fluids, higher anisotropy values (> 5%) for typical frequency ranges of 4 Hz, where the deeper seismic events analyzed always presented lower frequency ranges than the shallower ones. From local and regional events (SKS events), Audoine and Savage (2004) observed a frequency-dependent anisotropy, finding high splitting time values (δt = 2.5 ± 0.2 s) for lower dominant frequencies (~ 0.0625 Hz), where the influence of fluid-filled cracks was considered as an important effect. Savage et al. (1990) observed for low dominant frequencies, shear-wave velocities of 3.3 km/s along with anisotropy from 0.18 to 4.3%, where fluid-filled cracks and microcrack were also considered as possible anisotropic causes. High S-wave attenuations and lower dominant frequencies have been observed when seismic waves pass through zones where the magma is molten or partially molten (e.g., Latter 1981; Gerst and Savage 2004; Vanorio et al. 2005). Likewise, non-permeable pathways and chemically sealed fractures have also been considered for reduced splitting times (Vlahovic et al. 2002).
Equivalent-medium theories have been used to model the elastic response of fractured rocks, assuming fractures as rotationally invariant ‘penny-shaped’ cracks. In such models, frequency-dependent anisotropy has also been observed by the influence of the alignment of inhomogeneities (e.g., fractures, fine layers, or fluid flow in porous rocks with micro-cracks and macro-fractures, Liu et al. 2003), also with decreases in δt and anisotropy as frequency ranges increases (e.g., Chesnokov et al. 2001; Liu et al. 2003). Chapman (2003) showed that larger fractures can introduce additional dispersion at lower frequency ranges, where anisotropy decreases (from 8 to 4%) as frequency increases (from 0.5 to 3.5 Hz). Fluid inclusions in fractures have also been considered as an important feature that affects the seismic frequencies and significantly the anisotropy (Thomsen 1995). Liu et al. (2000) and Chapman et al. (2003) have evidenced this sensitivity with variations on the seismic frequency ranges and elastic wave velocities. In sonic and ultrasonic laboratory measurements, these circumstances are observed for different types of fluids, such as oil, gas, and brine (e.g., based on the squirt-flow model, Maultzsch et al. 2003; Chapman et al. 2003). These analyses showed how gas inclusions in fractures generate lower compressional velocities than oil and brine at lower log frequencies (~ < 2 Hz) (i.e., at higher percentage of anisotropy), but higher compressional velocities at higher log frequencies (> 3 Hz, Chapman et al. 2003) (i.e., at lower percentage of anisotropy). Meanwhile, oil presented higher compressional velocities than brine at those lower log frequencies, but similar at higher log frequencies (Chapman et al. 2003).
From seismic exploration studies, SWS parameters have been observed to be sensitive to fractured rocks and fluid-filled fractures (e.g., gas into vertically fractured rock decreases slow shear-wave velocities and frequency content (< 12 Hz), van Der Kolk et al. 2001; Kozlov 2004). Shear-wave splittings have been observed to be higher for gas-filled than for liquid-filled fractures (van Der Kolk et al. 2001). Stratifications also tend to generate changes in the seismic frequencies (e.g., Werner and Shapiro 1999), where increases and decreases in the frequency content are a function of permeability (Van der Kolk et al. 2001; Kozlov 2007). Likewise, the level of anisotropic arrangement has been considered as an influential factor in the frequency ranges. Lower dominant frequency ranges have been linked to fracture alignments presenting directions to the main fracture groups (Liu et al. 2003) or when they are more organized (Maultzsch et al. 2003). Nonetheless, increases in dominant frequencies may be observed when the anisotropic arrangements decrease (Marson-Pidgeon y Savage 1997).
The Tres Vírgenes Volcanic Complex (TVVC) constitutes a heterogeneous and anisotropic environment, whose tectonic background has been strongly modeled by the opening of the Gulf of California. Within the TVVC area, the Tres Vírgenes Geothermal Field (TVGF) has been in operation since the 1980’s, whose effects on the shallower geology have been documented by numerous geological, geochemical, and geophysical studies (e.g., Campos-Enríquez 1992; López-Hernández et al. 1995; Romo et al. 2000; Wong et al. 2001; Lermo et al. 2010; Prol-Ledesma et al. 2016; Avellán et al. 2018, among others). Here, in this work, the SWS technique is used to analyze 558 seismic waveforms collected from 2009 to 2013, whose splitting parameters allowed defining those zones and pathways with the highest fracture densities in the TVVC, mainly linked in this work with the percentage of anisotropy, as well as the depths where pervasive anisotropy and high fracturing begins. Furthermore, possible effects of different degrees of fluid content in fracture systems, sealed fracture systems, and magmatic phenomena were also analyzed from the behavior of the dominant frequency peaks, S-wave velocities, anisotropy, and splitting delays. This was done by restricting the selection of seismic events to smaller study areas around the seismic stations (e.g., < 0.035° in latitude and longitude), and considering only those anisotropic signals with angles of incidence less than 45° to avoid the distortion in the incoming wave, influences of converted phases, and alterations in the splitting measurements as recommended by Evans (1984) and Booth and Crampin (1985).
General geology
The tectonic interaction between the Pacific and North American plates has structurally affected the Baja California Peninsula (BC) (inset showing the study area, Fig. 1). The interaction between these tectonic plates, along the Pacific coast of Mexico and the southwestern USA, produced Cenozoic magmatism since 25 Ma (Atwater 1989; Stock and Hodges 1989). At about 12.5 Ma, the Farallon paleo-plate stopped subduction beneath the Pacific and North American plates and started the opening of the Gulf of California with an N–NW oblique-strike-slip movement (Stock and Hodges 1989; Lonsdale 1991). Subsequently, the tectonism was followed and controlled by the deformation system related to the opening of the Gulf of California (Conly et al. 2005). This deformation system was characterized by an NW compressive stress field sub-parallel to the main rift margin faults with an E–W and E–NE extensional field, attributed to both local and regional tectonic processes (Bonini et al. 2019). In the Pliocene, an extensive deformation produced a set of normal faults and tilted blocks with preferential directions NW–SE, N–S, and NE–SW (Stock and Hodges 1989; Garduño-Monroy et al. 1993), as well as N–S trending fault systems (Coletta and Angelier 1981).
In the Pliocene–Quaternary, post-subduction magmatism took place with the ascent of magmatic bodies, which gave rise to the El Aguajito Caldera (EAC) and the La Reforma Caldera (LRC) (Garduño-Monroy et al. 1993; Demant 1981, 1984). On these post-subduction, volcanic rocks were emplaced the El Viejo (EVV), El Azufre (EAV), and La Virgen (LVV) volcanoes following the southwestern continuation of the NE–SW Cimarrón fault that crosses the EAC (e.g., Avellán et al. 2018). These three volcanoes form the so-called Tres Vírgenes Volcanic Complex (TVVC) (Gastil et al. 1975, 1979; Sawlan 1981), located in the northwestern portion of the Santa Rosalia basin (SRB) (Fig. 1), which is a Plio–Quaternary depression with an NW–SE trend (Demant 1981). The evolution of the TVVC is marked by periods of erosion and volcanic quiescence (López-Hernández et al. 1995).
In the TVVC area, regional NW–SE faults have been observed, whose origin has been associated with the Gulf of California opening (Garduño-Monroy et al. 1993; Macias-Vásquez and Jiménez-Salgado 2012). Fault systems, such as Mezquital, Bonfil, and Campamento correspond to normal faults with right-lateral components (e.g., Garduño-Monroy et al. 1993; Macias-Vásquez and Jiménez-Salgado 2012), which are located to the northwest and southwest of the TVVC (Fig. 1). The Mezquital fault bounds to the west the San Francisco Range (SFR), while the Campamento Fault limits to the east of the Santa Lucia Range (SLR). Local normal faulting has also been mapped (e.g., El Azufre, El Partido (EPO), El Viejo 1 (EV1), El Viejo 2 (EV2), and El Volcán faults), which affected the EVV and EAV. The La Reforma fault, a right-lateral strike-slip fault with a minor normal component, is approximately tangent to the LRC at its southwestern limit (e.g., Garduño-Monroy et al. 1993; Macias-Vásquez and Jiménez-Salgado 2012). The EAC is bounded to the west and the east by El Aguajito and El Alamo faults, respectively. N–S and NE–SW trending faults traverse this eruptive center (i.e., El Cimarrón Fault). N–S to NE–SW minor fault systems are observed to the west and southwest of the TVVC (Fig. 1). Northwest of LVV, the La Virgen fault, seems to be a continuation of the El Campamento fault to the southeast.
Mexico’s Federal Commission of Electricity (CFE) has mapped fault systems to aid geothermal exploitation in the TVVC and neighbouring EAC (e.g., López-Hernández et al. 1993; Gomez and Rocha 2009; Benton et al. 2011). Hydrothermal manifestations have been located in some parts of the main fracture systems [e.g., the EV1 and El Azufre faults, Prol-Ledesma et al. 2016], but also in the Las Viboras (LVF) and EV1 faults (Portugal et al. 2000). From electromagnetic studies (Romo-Jones et al. 2018), a hydrothermal potential zone was inferred, which is located between the TVVC and the EAC (Fig. 1), whose depths reach between 1.5 and 12 km. Furthermore, in the TVVC area has been considered an exploitation reservoir of 6 km2 and a thickness of 0.3 km (Tello-López et al. 2015), with a thermal state characterized by temperatures of 300 °C (Portugal et al. 2000). Romo-Jones et al. (2000) and Wong et al. (2001) suggested that the TVVC area presents fractured rocks and fluids with temperatures higher than 240 °C at depths between 1.5 and 2.5 km. Since the TVVC is located in the southern part of BC, a homogeneous belt with a Curie isotherm could reach between 15 and 21 km in depth (Campos-Enríquez et al. 2019).
Data analysis and methods
From 2009 to 2013, the CFE operated a network of twenty seismic stations in and around the TVVC (Lermo et al. 2014) spanning approximately an area of 15 times 15 km. Of this network, only ten sites with seismic stations were part of a permanent seismic network (Fig. 2), which consisted of Guralp CMG-6TD broadband seismographs with three digital components and a sampling interval of 0.01 s. The number of stations in operation changed during this study period (see Table 1).
A total of 558 seismic waveforms with a clear reconnaissance of the arrivals of the P and S phases were analyzed. Their magnitudes Md, based on duration, vary from 1.0 to 3.0 with depths from 1.0 to 10.0 km, which were calculated with a minimum of four stations, using the SEISAN package (Ottemöller et al. 2013) and considering a location error (RMS) less than 0.5 km. Most of the seismic events were mainly concentrated in the central part of the TVVC, in the area limited to the west by La Virgen Fault and to the east by La Reforma Fault, and concentrated in the area of the EPO, EV1, and EV2 faults (Fig. 2). Secondary seismic groups can also be observed to the north of the EVV, near the El Cimarron Fault, and also to the south and southeast of LVV, near stations TV21, TV22, and TV23.
To estimate the shear-wave splitting parameters (ϕ and δt), the seismic waveforms were selected and processed following the methodology of Ando et al. (1980) and Bowman and Ando (1987). The developed hybrid code is based on the cross-correlation method, whose details are given in Chacón-Hernández, et al. (2021b). In short, for each event, the horizontal waveform components (N–S and E–W) were rotated in the horizontal plane, finding the maximum of the cross-correlation function within an ideal time window and considering an azimuth range from − 180° to 180°, all of which enable to split into two orthogonally polarized components the S-wavefield. The angle with the maximum cross-correlation function provides the fast polarization direction, while the difference in time between both phases (S1 and S2) represents the delay. Seismic signals with an incident angle higher than 45° (outside the shear-wave window) were discarded to avoid distortion in the incoming wave, ensuring that the particle motion is not contaminated by S- to P-wave conversions, as recommended by Evans (1984) and Booth and Crampin (1985). To better differentiate S1 and S2, the waveforms have been analyzed and subjected to Butterworth filters, especially band-pass filters with frequency range between 0.1, 5, 10, 15, and 20 Hz. However, in some cases, low-pass filters with frequency limits of 15 and 20 Hz were also employed. To calculate the percentage of anisotropy (A), the average anisotropy along the raypath is approximated by the expression:
where Vs is the shear-wave velocity, δt is the delay time parameter, and r is the source–receiver distance (e.g., Maher and Kendall 2018). The Vs values were approximated considering the arrival time difference between the P and S phases of each seismic event analyzed and the local ratio Vp/Vs = 1.70 (Lermo-Samaniego et al. 2014) used in the study area.
Results
Delay time and the anisotropy strength
Mean delay times (MDT) with their respective errors (Er) (95% confidence level) were obtained from 770 δt values for each station and for each year of the studied period (see Table 2). Stations TV01, TV03, TV04, TV11, TV18, and TV21 presented the highest MDT values, whose variations between years were notable in some cases. For instance, at station TV01, values of MDT range from 0.0531 s during 2010 to 0.0367 s during 2011; while at station TV03, values of MDT vary from 0.0356 s during 2011 to 0.0519 s during 2013 (see Table 2 and Fig. 3). Some of these MDT values were calculated with few data (e.g., for station TV04 during 2010 and 2011; for station TV18 during 2010 and 2013, see Table 2 and Fig. 3). On the other hand, the lowest MDT values can be observed at some stations for particular years (e.g., at station TV05 during 2010 and 2012; at station TV24 during 2012 and 2013, Table 2 and Fig. 3). The associated errors (95% confidence intervals) do not show significant changes, but the TV03 and TV18 stations, both during the years 2010 and 2013, show large error bars compared to the other years and stations (Table 2 and Fig. 3).
The mean anisotropy percentage (MAP) was obtained with its respective error (95% confidence level) for each seismic station and each year (Table 3 and Fig. 4). The highest A values are mainly observed in station TV01 during 2010 and 2012; in station TV04 during 2011 and 2013; in station TV11 during 2011; and in station TV18 during the years 2010 and 2013, generally exceeding 2.0%. Noteworthy is a marked increase from 2012 to 2013 in all stations, except for the TV01 and TV11 stations, which show a decrease (Fig. 4). Most of the MAP values are between 0.54 and 2.53%, whose associated errors (95% confidence interval) approximately overlap in some years (e.g., station TV03 during 2010 and 2013; station TV04 during 2010, 2011, and 2013; station TV05 during 2011; station TV11 during 2010; station TV18 during 2010 and 2013; station TV22 during 2011; station TV23 during 2011 and 2013), which indicate notable variations in anisotropy measurements (see Fig. 4). The largest variation in the error ranges is observed in stations TV04, TV18, and TV21, which also present high MAP values, while lowest errors are mainly observed in stations TV01 and TV11 (see Table 3 and Fig. 4).
All data used to calculate the MDT and MAP values at each seismic station (Tables 2 and 3 and Figs. 3 and 4) are collected in Fig. 5, showing the distribution of the δt and A values with respect to depth. Their respective MDT and MAP values are indicated. The highest δt and A values (> 0.1 s and 5.5%) are mainly located in a narrower depth range, approximately for seismic events from 3.0 to 7.0 km for the δt (Fig. 5a) and A values (Fig. 5b). Lower values (< 0.05 s and 2.0%) can be associated with seismic events of all depths (from 3.0 to 10.0 km), but values for events deeper than 9.0 km do not exceed 0.1 s and 3.0%, respectively. Their respective mean values MDT and MAP were calculated along with their respective errors at a 95% confidence level.
Spatial distribution of the highest anisotropy percentage
Figure 6 shows the hypocentral distribution of 60 seismic events recorded at all stations and analyzed to calculate the A value. The range represented a delay time of 0.075 s for the A value of 4.02% to a delay time of 0.104 s for 10.3%. A values above 4.02% are important to delimit areas with high fracturing levels (e.g., Crampin 1994). The highest A values are found in the area of the volcanic complex, especially between EVV and EAV, near the El Azufre, El Volcán, EPO, EV1, and EV2 faults and other unnamed faults (see Fig. 6). Respective depths of the seismic events analyzed range between 3.0 and 6.5 km. Other seismic events for which significant A values have been obtained are located to the south and southwest of LVV, close to the La Virgen and Mezquital faults and to the TV21, TV22, and TV23 stations, but also near the El Volcán fault and the TV05 station, whose depths mainly range between 6.0 and 7.0 km.
Analysis of the main pathways with high fracturing
In particular and to simplify the estimation of the anisotropy percentage, the raypath lengths used to normalize δt were approximated by the lengths of straight lines joining the hypocentral depth of each event and the recording station. Figure 7a shows all pathways (straight lines) joining the seismic sources and stations. These pathways were differentiated based on three criteria: (1) Only those anisotropic pathways with anisotropy percentages greater than 4.0% are considered; (2) ranges from 4.0 to 7.0, 7.1 to 9.0%, and greater than 9.0% are used to differentiate high levels of fracturing; (3) Most of these pathways had angles of incidence less than 45°. Figure 7a and b show in isometric and map views the pathways with an anisotropy percentage above 4.0%, which help to highlight the zones with the highest fracture degrees. These figures include pathways obtained from seismic events from all the years of the studied period. There are no pathways with large fracture levels arriving to stations TV05 and TV24. In the isometric view, the pathways with the highest percentage of anisotropy (i.e., A ≥ 7.1%) are represented by those straight lines formed by both sequences of dark red squares with black frames and pink squares with light red frames, while those pathways with A values between 4.0 and 7.1% are represented by sequences of blue squares (see symbology). All these anisotropic pathways were derived from seismic events that have their origins at depths between 3.0 and 7.0 km, but mostly at depths between 4.0 and 6.0 km (Fig. 7b).
These anisotropic pathways were projected onto a horizontal plane (Fig. 7c). A high fracturing zone can be noted to the east and northeast of EVV (Fig. 7c), where the La Reforma and El Azufre faults (numbers 1 and 10 in Fig. 7c) interact with the El Cimarron (number 9 in Fig. 7c) and other unnamed N–S to NE–SW faults (i.e., faults not marked with numbers in Fig. 7c). High fracturing is also present around EAV, where El Volcán Fault (number 2 in Fig. 7c) and minor NW–SE faults (possible southward extensions of EV1, EV2, and EPO faults (numbers 5, 6, and 7 in Fig. 7c), intersect unnamed N–S to NE–SW faults. Another zone with a high level of fracturing is also indicated along the EV2 and EPO faults (numbers 6 and 7 in Fig. 7c). In general, high fracturing is inferred to be beneath the EVV and EAV (Fig. 7c). These pathways mainly cross the substratum of La Reforma, El Volcán, EV1, EV2, and EPO faults, as well as to the EVV, LVV, and EAV structures. Other pathways can also be observed near the La Virgen-El Campamento and El Mezquital faults, arriving at stations TV21, TV22, and TV23 (Fig. 7c). Figure 7d represents an approximately NW–SE vertical section through stations TV01, TV04, and TV18 following the La Reforma and El Azufre faults, highlighting pathways with high percentage of anisotropy from seismic events at depths of 3.0 to 6.5 km. Figure 7e represents an NE–SW vertical section through stations TV01 and TV18, highlighting pathways with high percentage of anisotropy from seismic events at depths of 3.5 to 6.5 km.
In Fig. 8a, the anisotropic pathways with the highest fracture densities are projected onto a geological profile, where most of the anisotropic trajectories converge toward the EVV, an intermediate concentration beneath the EAV, with a lower concentration around the LVV. The stratigraphic units are described in Table 4 according to Avellán et al. (2018). The origins of the pathways begin from seismic events inside the Peninsular Ranges Batholith unit (PRB) (approximately from 7.0 to 4.0 km) and cross other more superficial geological units (i.e., in the Santa Lucia-San Francisco (SL-SF), Esperanza Basalt (EB), Aguajito ignimbrite (Ag), Lower Viejo dacitic lava dome (LVdld), Puerta dacitic lava dome (Pdld), and Upper Viejo dacitic lava dome (UVdld) units), as well as different faults. Figure 8b shows the projected anisotropic pathways onto a plane (map view) at sea level (i.e., 0 km), which approximately coincides with the top of SL-SF unit. In Fig. 8c, the intersection of the anisotropic pathways is shown onto a section of approximately 1.0 km deep below sea level that approximately coincides with the top of the PRB unit. Meanwhile, Fig. 8d, e, and f show the anisotropic pathways projected onto planes at depths of 2.0, 3.0, and 4.0 km, reaching deeper parts of the PRB unit. These projected anisotropic pathways show how some areas with high fracturing cover these geological units.
Analysis of delay times vs. seismic frequencies and anisotropy vs. shear-wave velocities
Two examples of seismic events with similar hypocentral parameters and recorded at station TV11 (the event 2010-05-13-1938-31S.CFE of Fig. 9a: Latitude: 27.5201°, Longitude: − 112.5792°, Depth: 5.2 km; the event 2010-05-13-1958-26S.CFE of Fig. 9b: Latitude: 27.5209°, Longitude: − 112.5792°, Depth: 5.1 km) illustrate variations on the shear-wave splitting delays and spectral frequency contents. Both seismic events were subjected to band-pass filters using ranges from 5 to 15 Hz, respectively, to obtain the splitting times, where their fast S1 and slow S2 shear waveforms as well as their picked onsets are shown. In the first event (Fig. 9a), the δt value obtained was 0.056 s, with a range of dominant frequencies from 0 to 5.95 Hz; while for the second event (Fig. 9b), the δt value obtained was 0.0094 s, with a range approximately from 0 to 9.0 Hz. In this example, the delay time is shorter when the frequency content is higher and slightly more extended (Fig. 9b), but larger delays when lower frequencies are dominant (Fig. 9a), although this plot shows a second important peak around 5 Hz. Both dominant frequencies were obtained for the fast S-wave forms without filtering to avoid losses and attenuations of the original frequencies.
Figure 10 plots the relationships between values of δt vs. the main seismic frequencies fmax (Fig. 10a), which were obtained from the dominant peaks in the seismic frequency spectra from the fast S-waveforms. Likewise, the percentage of anisotropy A vs. shear-wave velocities Vs (Fig. 10b), and fmax vs. Vs values (Fig. 10c) of 77 seismic waveforms recorded during 2010 at stations TV01, TV03, TV04, TV11, and TV18 (the closest stations to the geothermal site) is plotted, where the depths of the analyzed seismic events varied mainly from 3.5 to 7.0 km. To avoid filtering, only this year is assessed because most of the fast seismic waveforms presented less noise (i.e., a signal-to-noise ratio greater than 5.0) in contrast to the data from the rest of the years with greater variation. This allowed, in a more exemplified way, to analyze fmax along with the behavior of the δt, Vs, and A parameters of the used data. Nonetheless, in the analysis of the highest anisotropic pathways, information from all years was considered.
Trying to link some effects and phenomena, values of δt, fmax, Vs, and A are classified and analyzed according to their behaviors and from information from previous studies. Intermediate and high δt values (above 0.03 s) associated with lower fmax values (e.g., from around 0.01 to 1.0 Hz) were grouped in the dashed square GA1 (see Fig. 10a), considering possible effects related to fracture systems with lower fluid content (e.g., van Der Kolk et al. 2001; Liu et al. 2001; Liu et al. 2003; Kozlov 2004). Intermediate and high δt values (above 0.03 s), associated with higher fmax values (e.g., above 1.0 Hz), were grouped in the dashed square GA2, considering possible effects of fracture systems with higher fluid content effects (e.g., Chesnokov et al. 2001; Liu et al. 2001; Kozlov 2007). Some data from stations TV01, TV03, TV04, TV11, and TV18 showed lower δt values (from 0.01 to 0.02 s) for different fmax values (between 0.5 and 2.0 Hz), which were grouped in the dashed square GA3 (see Fig. 10a). Added to this, data from stations TV04, TV11, and TV18 with lower Vs (e.g., between 1.0 and 2.5 km/s) and A values (e.g., between 0.01 and 2.0%) were also grouped in the dashed square GB1 (see Fig. 10b), this was done considering the possible existence of sealed fractures and effects of magmatic bodies (e.g., Vanorio et al. 2005; Latter 1981). Increasing trends between the A and Vs values are mostly observable for stations TV01, TV11, and TV18 between 0.01 and 5.55%, for A values and between 1.0 and 4.0 km/s for Vs values, but less clear at stations TV03 and TV04 (Fig. 10b).
Figure 10c shows the relationship between the fmax and Vs values as a complement of Figs. 10a and b, where most of the data of stations TV01, TV03, and TV18 presented Vs values between 2.5 and 3.0 km/s for fmax values less than 1.0 Hz, while most of the data of the TV04 station presented Vs values above 3.2 km/s for fmax values less than 1.0 Hz. Two cases can be considered for the data of the TV11 station; in the first, the Vs values ranged between 2.2 and 3.6 km/s for fmax values above 1.0 Hz, while for the second case, the Vs values ranged between 1.0 and 2.5 km/s for fmax values less than 1.0 Hz. Particular cases are observed for data from stations TV01, TV04, and TV11, with a low range of Vs and fmax values (e.g., from 1.0 to 2.5 km/s; from 0.5 to 1.0 Hz, respectively), which were grouped in the dashed square GC1. This grouping is supporting the possible existence of sealed fractures and magmatic body effects. Stations TV11 and TV18 presented the highest fmax values (between 1.5 and 2.0 Hz) for Vs values between 2.2 and 3.0 km/s, which are grouped in the dashed square GC2, this is also supporting the presence of fracture systems with higher fluid content. Stations TV01 and TV04, together with other fewer data of other stations, presented the highest Vs values (from 3.0 to 4.0 km/s) for lower fmax values (between 0.5 and 1.0 Hz), which were grouped in the dashed square GC3 supporting the existence of fracture systems with lower fluid content effects. The data between GC1 and GC3 squares presented a range of Vs values mainly between 2.5 and 3.0 km/s, which do not exceed 1.0 Hz. Some data of the GA1 and GA2 groups present Vs values above 2.5 km/s (covering part of the GC1 and GC3 groups) with A values above 2.5 and up to 8.6%. In the GA3 group, lower A values (less than 1.0%) with a specific range of Vs values (between 2.0 and 3.8 km/s) could be considered to minor fracture systems with lower effects of fluid content or sealed fractures. The data between the GC1, GC2, and GC3 groups would not clearly evidence one phenomenon as mentioned above (Fig. 10c), but rather a combination of the presence of several phenomena. Station TV01 presents a greater amount of data, while stations TV03 and TV18 comprise a smaller amount of data.
Figure 11 shows the epicenter locations of each seismic data group analyzed in Fig. 10. The seismic events of the GA1 group (events in brown color and recorded at each station as shown in the symbology, Fig. 11a), originated mainly from the north and south of EVV and EAV and near the TV11 station (Fig. 11a), present a depth range from 3.6 to 6.8 km, but the seismic signals recorded at station TV03 have hypocenters located in a narrower depth range (i.e., more concentrated around a depth range, from 4.6 to 5.1 km, Table 5). The seismic events considered for the GA2 group (events in blue color, Fig. 11b) are originated from several locations along the EAV and EVV, whose depths vary from 3.5 to 6.0 km. The origin of seismic events in some stations presented narrower depth ranges, going from 5.5 to 6.0 km at station TV03, 5.5 km at station TV04, and from 5.0 to 5.2 km at station TV11 (Table 5). The area comprising seismic events of the GA3 group (events in cyan color, Fig. 11c) is broader and includes the locations of groups GA1 and GA2. The seismic events of these groups are mainly located around EAV and EVV and to the south of EAV, with depths range from 4.1 to 6.0 km, presenting the TV04 and TV18 stations with narrower depth ranges (from 5.4 to 6.0 km, and from 4.9 to 5.3 km, respectively, Table 5). The origin of seismic events in group GB1 (events in light pink color, Fig. 11d) is mainly located around EVV and EAV and near stations TV01, TV11, and TV18, whose depths range from 4.0 to 7.0 km, presenting narrower depth ranges the TV04 station (from 5.2 to 5.5 km, Table 5). The origin of seismic events analyzed in the GC1 group (events in brown color, Fig. 11e) is mainly located to the west of EVV and EAV, with depths from 4.4 to 6.0 km, presenting the TV01 and TV04 stations narrower depth ranges (from 5.1 to 5.7 km, and from 5.0 to 5.7 km respectively, Table 5). Some of their locations coincide with that of group GA1. The origin of seismic events analyzed in the GC2 group (events in blue color, Fig. 11f) is located around the volcanic complex, with a depth range from 5.0 to 6.0 km, presenting all the stations narrower depth ranges (see Table 5). The origin of seismic events analyzed in the GC3 group (events in cyan color, Fig. 11g) is located around the EAV and EVV structures and mainly located in north and south of EAV and EVV and near the TV11 and TV18 stations, with a depths range from 4.4 to 6.0 km. Their location correlates with that of the GA3 and GB1 groups.
Figure 12a and b display the relationships between δt vs. fmax and A vs. Vs values of 16 seismic waveforms recorded during 2010 at stations TV01, TV03, TV04, TV11, and TV18. This was done considering a hypocentral seismic depth between 4.0 and 5.0 km. Meanwhile, Fig. 12c and d presents these relationships for 49 seismic waveforms considering a hypocentral seismic depth between 5.0 and 6.0 km. The plots seem to show differences, with fmax values reaching a maximum of 1.0 Hz for those seismic events with a depth range between 4.0 and 5.0 km (Fig. 12a). The seismic events with a depth range from 5.0 to 6.0 km can reach up to 2.0 Hz, although most of the data present fmax values around 1.0 Hz (Fig. 12c). Likewise, a narrow range of Vs values (between 2.0 and 3.8 km/s) is observed for those seismic events with a depth range between 4.0 and 5.0 km (Fig. 12b), spanning a wide range of A values from 0.02 to 6.0%. Meanwhile, for those seismic events with a depth range between 5.0 and 6.0 km, a range of Vs values from 2.0 to 3.5 km/s is observed, with some Vs values less than 2.0 and above 3.5 km/s. The A values span a wide range from 0.02 to 5.0% (Fig. 12d).
Discussion
Fracturing systems with respect to depth
In Fig. 13, are shown the fast polarization directions from seismic events originated at different depth intervals (the hypocenters of the used events are shown in Fig. 15). Only those seismic events that arise in the close neighborhood of each of the stations TV01, TV03, TV11, and TV18 [< 0.035° in latitude and longitude and with angles of incidence less than 45° (Evans 1984; Booth and Crampin 1985)] were considered in this analysis. The main relative fast polarization direction observed at all depths is NW–SE, whose associated mean fast polarizations M vary approximately between − 120° and − 13.2° (obtained with the aid of the CircStat program by Berens 2009). The mean resultant length R, which gives a quantitative estimate of the data variance, falls mainly above 0.3 but lesser than 0.5 at the four analyzed stations, which could represent an intermediate data clustering (e.g., less than 0.3 could represent a bad clustering, Peng and Ben Zion 2004). The TV01 station presented the highest R values for more depth ranges (i.e., > 0.52 except in the depth range of 6–7 km), whose mean polarizations follow the orientation of the El Volcán fault (e.g., Fig. 2). Some other fast polarization directions have also been observed in these stations for different depth levels (see Fig. 13), which evidenced the existence of fracture systems in other directions. For instance, for those events originating between 3.0 and 4.0 km depth and for stations TV03 and TV18, WNW–ESE and NE–SW polarization directions are also observed (Figs. 13a and b). For seismic events in the depth intervals of 4–5 and 5–6 km, NNE–SSW and NE–SW secondary polarizations are a feature at all four stations except at station TV11 (Fig. 13c). These NNE–SSW and NE–SW polarizations are of lower importance at the 3–4 km depth interval in all stations except at station TV18 (Fig. 13d). For seismic events at deeper levels, the presence of NNE–SSW and NE–SW fast polarizations is also observed, but with low importance (e.g., seismic events recorded at station TV01 with focal depths from 6.0 to 9.0 km; seismic events recorded at station TV03 with depths from 6.0 to 7.0 km; seismic events recorded at station TV11 with depths from 6.0 to 8.0 km; seismic events recorded at station TV18 with depths from 6.0 to 8.0 km, Fig. 13). At station TV01, behaviors between values of ϕ and fmax show a large concentration between − 75 and 0° for fmax values less than 1.0 Hz, mainly related to the 6–7-km depth interval (Fig. 13a). At station TV03, no particular behavior is observed for each depth interval, except for the 4–5-km interval with higher fmax values, which reach between 4.0 and 6.0 Hz for ϕ values between 0 and − 70° (Fig. 13b). At station TV11, most of the ϕ values fall between − 90° and 0° for most of the depth intervals, with values less than 1.0 Hz; nonetheless, for the particular case of the 6–7 km depth interval, the fmax values are higher than 1.0 Hz (Fig. 13c). At station TV18, in the 4–5 and 5–6-km intervals, most of the results fall between 10° and -90°, whose fmax values are in a range of 0.1 and 2.0 Hz with some particular cases higher than those (Fig. 13d).
Figure 14 shows the relationship between the δt parameter and the hypocentral distance for stations TV01, TV03, TV11, and TV18, considering seismic events less than 0.035° in latitude and longitude, and depths less than 5.0 km. This depth limit is considered only to establish the depth at which the pervasive anisotropy begins. Theoretically, at greater hypocentral distances, higher δt values would be expected. However, in both plots, it is possible to observe for each station both high and low δt values for given hypocentral distances. In particular, an unusual behavior of high δt values for smaller hypocentral distances could be an indication of a high concentration of fractures at shallower depths. Thereby, in Fig. 14a, an anisotropic and pervasive stratum can be considered for some events recorded in station TV01 to start at a hypocentral distance of 3.5 km for some values observed, for which the highest normalized delay time is δtn = 31.95 ms/km, while a mean with a 95% confidence level is δtn = 10.6 ± 0.007 ms/km. Seismic events recorded at station TV03 do not show clear evidence of a pervasive stratum. In Fig. 14b, this unusual high fracturing is also possible to observe for some events recorded in station TV18 from hypocentral distances of 4.5 km, whose highest normalized delay time is δtn = 26.17 ms/km, while a mean with a 95% confidence level is δtn = 10.77 ± 0.0047 ms/km. Likewise, few seismic events recorded at station TV11 seem to present an unusual behavior from a distance of 3.5 km, where the highest normalized delay time is δtn = 16.3 ms/km, while a mean with a 95% confidence level is δtn = 7.1 ± 0.0036 ms/km.
Strength of anisotropy and main pathways
In the TVVC, high individual values of δt and A reaching up to 0.1616 s and 10.03%, respectively, indicate a high fracturing degree similar to results from other geothermal zones (e.g., 18.0% at the Takinoue geothermal area in Japan, Kaneshima et al. 1988; 7.0% at Uturuncu Volcano in Bolivia, Maher and Kendall 2018; 10.0% at Aluto Volcano in Ethiopia, Nowacki et al. 2018). The mean values of all δt and A data (MDT and MAP) were 0.0425 s and 1.823%, respectively (Fig. 5). The highest MDT value was 0.0587 s at station TV21 (Table 2; Fig. 3), while the highest MAP value was 2.53% at stations TV11 and TV18 (Table 3; Fig. 4), which are below the 4.5% limit proposed by Crampin and Leary (1993) and Crampin (1994) to differentiate between a low (below limit) and a high (above limit) fracture density. Thus, the variation range of the MAP values, 2.53 to 0.54% (lowest and highest levels), also indicates the existence from intermediate to low degree of fracturing in some areas (see Figs. 4 and 5).
High anisotropy (A > 4.5%, Crampin 1994) is mainly located beneath EAV and EVV, following the El Azufre, El Volcán, EPO, EV1, EV2, and La Reforma faults as well as some minor faults perpendicular and sub-parallel to the La Reforma fault (see Figs. 6, 7 and 8). The hypocentral seismic depths are mainly located between 3.0 and 6.5 km (Figs. 5a, b, and 6). Other important fracturing zones are also observed near LVV and toward the La Virgen-El Campamento, El Volcán, and El Mezquital faults, with hypocentral seismic depths between 4.0 and 6.0 km (Figs. 6 and 7). These anisotropic pathways delimit fracturing zone approximating conical shapes delimited by the pathways with vertices at stations TV01, TV04, TV11, and TV18, which can be observed at different depth levels depending on the origin of the seismic events analyzed (see Figs. 7a, 8c, d, e, f, and g). The conical shapes are not an intrinsic property but a product of the observation geometry (where the vertices are constituted by the seismic stations and the base is delineated by the hypocenters). Large fracturing is observed in a band around the La Reforma–El Azufre fault system, between stations TV01 and TV18 (Figs. 6, 7c, d, and 8a), where anisotropic pathways intersect in a depth range of approximately 2.0 to 5.0 km (see Fig. 7c). These intersections present a horizontal extension that could reach approximately up to 2.5 km between both stations (see Fig. 7b). Between stations TV11 and TV18, anisotropic pathways also intersect in a depth range of approximately 2.0 to 5.0 km, but closer to TV18 (see Fig. 7d), with a horizontal extension that could reach approximately up to 3.0 km (see Fig. 7b). Another zone is located in the southern front of EVV and EAV. The last one delineates a band along the EV2 Fault, near station TV04 (Fig. 7c) and where geothermal wells are located (Fig. 7b).
The areas with high fracturing correlate with the main NW–SE fault systems, which reach down to 8.0 km in depth (see Fig. 13), and are controlled by NW–SE regional fracture systems as mentioned by Chacón-Hernández et al. (2021a) (i.e., the El Azufre, La Reforma, El Volcan, EV1, EV2 and EPO faults), which are parallel or sub-parallel to the California Gulf transpression direction. This depth range is mainly located inside the plutonic rocks of the Peninsular Ranges Batholitic (Gastil et al. 1975), whose top has been observed at a depth of 1.13 km below the surface (e.g., Garduño-Monroy et al. 1993). The highest δt and A values indicate that from the upper part of the granitic basement (PRB unit, Fig. 8a) there are high degrees of fracturing. These high degrees of fracturing also span the shallowest geological units (i.e., SL-SF, EB, Ag, LVdld, Pdld, and UVdld, see Table 4, Fig. 8a, b, and c), which are strongly affected by the exploitation of the geothermal site and by natural hydrothermal phenomena, generating stratums with pervasive fracturing that take place from at least 3.5 and 4.5 km in areas near to stations TV01, TV11, and TV18 (see Fig. 14).
Inference of fluid saturations and magmatic bodies with respect to depth
Fluid flow in fracture systems linked to hydrothermal phenomena or geothermal activities has been observed to facilitate coalescence, growth of cracks, and fault activations [e.g., in geothermal environments (Vlahovic et al. 2002; Main et al. 1990; Clarke et al. 2019), and their effects are being assessed in theoretical equivalent models, Maultzsch et al. 2003; Chapman et al. 2003]. Since TVVC presents both hydrothermalism and geothermal activity, an analysis between δt and fmax values was conducted along with the analysis of the Vs and A values to discriminate fluid saturation degrees in fracture systems. According to previous works (van Der Kolk et al. 2001, Liu et al. 2001; Liu et al. 2003; Kozlov 2004), the data of the GA1 group can indicate intermediate and large fracturing levels with a lower effect of fluid content, which contrasts to the data of the GA2 group (e.g., in previous works, Chesnokov et al. 2001; Liu et al. 2001; Kozlov 2007). Seismic events of both groups were recorded at five stations (i.e., the TV01, TV03, TV04, TV11, and TV18 stations), located around EVV and EAV, with a depth range from 3.6 to 6.8 km for the GA1 group and from 3.5 to 6.0 km for the GA2 group. For the GA1 group, the seismic events recorded at the TV03 station presented a narrower depth range (from 4.6 to 5.1 km). Some of the hypocentral data of the GA1 group also form part of the GC3 group, mainly those events recorded at stations TV01 and TV04, where a narrower depth range from 5.0 to 6.0 km was observed at station TV04. These relationships between some data of the GA1 and GC3 groups would imply intermediate and large fracturing levels, which could probably indicate fractures with lower fluid content, whereby higher Vs values are observed (i.e., between 3.0 and 4.0 km/s, Fig. 10c).
The origin of seismic events analyzed in the GA2 group also present intermediate and large ranges of δt values but a higher range of fmax values (i.e., above 1.0 Hz), which according to studies of Elkibbi (2004) and Rial et al. (2005) could be reflecting fracture systems under effects of higher fluid content or steam flow, whose Vs values present a decreasing from 3.6 to 1.5 km/s. The origin of seismic events analyzed in the GA2 group is located in a depth range between 3.5 and 6.0 km, but for stations TV03, TV04, and TV11, a narrower depth range was observed, mainly between 5.0 and 6.0 km (some seismic data are emphasized in the GC2 group) (see Table 5). This last depth range correlates with the 5–6-km depth interval of Figs. 12a and c, where higher fmax values were observed in some data, probably indicating a higher fluid content in fracture systems (e.g., for the GC2 group, Vs values range approximately between 2.0 and 3.4 km/s in some seismic data of stations TV11 and TV18), compared to the 4–5-km depth interval. This evidences variations in fluid contents from one depth interval to another in some areas, where probably the influence of geothermal activities is stronger in the 4–5-km depth interval and shallower depths, along with hydrothermalism phenomenon. A seismic tomography study conducted by Vilchis-García et al. (2019) considered compressional velocities VP < 4.25 km/s and a ratio of Vp/Vs < 1.75 km/s in a depth less than 4.0 km as a combination of fluids and gases in a caprock. Meanwhile, Vp/Vs > 1.75 km/s in deeper zones than 4.0 km was related to fluid saturation in rocks and probably cold magma crystalized. These results correlate to some extent with what was observed in our analyses.
Fracture systems chemically sealed or impermeable sealing caps have been observed in geothermal areas (e.g., The Coso Range, Vlahovic et al. 2002; Los Humeros, Arzate et al. 2018). In the TVVC area, Portugal et al. (2000) verified the existence of sealed fractures, which could be indicated by some data of the GA3 group, characterized by low δt values (e.g., δt values from 0.005 to 0.02 s) and fmax values from 0.5 to 2.0 Hz (see Fig. 10a). This is according to previous works that related sealed fractures with decreases in dominant S-wave frequencies (e.g., Latter 1981; Zhao et al. 2002). Areas with these features are mainly located to the west of EAV and EVV and to the south of EAV (see Fig. 11a) where the depth ranges of the analyzed events go from 4.1 to 6.0 km. The seismic events analyzed for the GA3 group were recorded in all stations (see Fig. 10a), but in stations TV04 and TV18 they presented narrower depth ranges (from 5.5 to 6.0 and from 4.9 to 5.3 km, see Table 5).
Changes in fast polarization directions at certain locations and depths are interpreted as indicating fracture systems in other orientations (e.g., Fig. 13), but they could also be due to the presence of magmatic intrusion systems or subvolcanic bodies. This is because the magmatic phenomena are capable of modifying the orientations of fractures in the rock volume (e.g., the 90° flip effect) by changes in the local stress field as has been considered in other previous works (e.g., Roman et al. 2011; Baird et al. 2015; Maher and Kendall 2018). Thus, the presence of important N–S, NE–SW, and E–W secondary polarizations observed for seismic events at deeper levels (e.g., depths ranges from 5.0 to 6.0 km at station TV01, Fig. 13a; depths > 4.0 km at station TV03, Fig. 13b; depths > 6.0 km at station TV11, Fig. 13c; depths > 5.0 km at station TV18, Fig. 13d) could be associated to magmatic phenomena.
The analysis between Vs and A values and between Vs and fmax values could support the presence of magmatic intrusion in the case of a correlation of the lowest Vs (from 1.0 to 2.5 km/s), A (from 0.1 to 2.5%, see Fig. 10b), and fmax values (lower than 1.0 Hz, see Fig. 10c) (i.e., some seismic data of the GB1 and GC1 groups). This is because, magmatic and volcanic phenomena reduce the Vs values (Vanorio et al. 2005), affecting the frequency contents and fast polarizations under conditions of high pore-fluid pressures (Crampin and Zatsepin 1997). These particular conditions are mainly found around EVV and EAV and near the TV01, TV04, and TV11 stations, related with the seismic events analyzed in the GB1 group for a focal depth range from 4.0 to 7.0 km (see Fig. 11 and Table 5) and in the seismic events analyzed in the GC1 group for a depth range from 4.4 to 6.0 km, with narrower depth ranges at stations TV01 and TV04 (from 5.1 to 5.7 and from 5.0 to 5.7 km, respectively, see Fig. 11 and Table 5). These depth ranges in the GB1 and GC1 groups could be correlated with the 5–6-km depth interval observed in Fig. 12d, mainly for some events recorded at station TV01, TV04, and TV11 with lower Vs and A values. In previous studies of seismic tomography (e.g., VP > 4.25 km/s and VP/VS > 1.75 km/s in zones deeper than 4.0 km, Vilchis-García et al. 2019), inversion of aeromagnetic data (magnetic sources in a depth range from 4.5 to 8.0 km, Avellán et al. 2019), and b value (b values between 1.1 and 1.5 for a range depth from 4.0 to 6.0 km, Antayhua-Vera et al. 2022) have also considered the presence of magmatic bodies, crystallized magma, or the emplacement of magmatic bodies (i.e., dikes).
Table 6 summarizes depths at which low, intermediate, and high fracturing zones are located together with their inferred different fluid contents. It also indicates the initial depths of pervasive anisotropy, as well as the possible presence of magmatic bodies. Figure 15 shows, in a conceptual sketch, the distribution of highly anisotropic rock volumes and the respective phenomena and processes interpreted to be their causes beneath the TVVC. Most of the main fault systems, that follow the regional stress and correlate with the fast polarization results (e.g., Fig. 13; see Chacón-Hernández et al. 2021a), cannot entirely explain the upper crustal anisotropy observed at the TVVC. Thus, the distribution, both vertically as across the TVVC, of the fracturing degree zones and their fluid content is uneven, but the distribution of high fracturing zones with high, intermediate, and low fluid content tends to start at least beneath 6.0 km depth (Figs. 5, 6, 7, 8 and 11, and Table 5) and extends toward the surface (e.g., the areas with the dashed blue lines and the distribution of the blue arrows, Fig. 15). The associated large anisotropy percentage implies that the rock volumes are essentially cracked and fractured, and in an unstable state due to high pore-pressures and/or fluid-filled cracks. In zones deeper than 6 km, the higher pressure and temperature conditions would indicate that fluids hosted in cracked volumes are in a super-critical state.
At shallower depths, there are also fractured zones with high fluid content and under high confining pressures linked to hydrothermal and geothermal processes that can generate cracks opening. Strata with pervasive anisotropy can be considered to begin at a 3.5-km depth for seismic data registered at stations TV01 and TV11, but at a 4.5 km depth for data recorded at station TV18 (high values of anisotropy and normalized delay times, Figs. 5b and 14), which correlates with the highest fracture concentrations and important permeable zones. These zones allow feeding the geothermal reservoir (e.g., see areas outlined with dashed brown lines and brown arrow distributions spanning up to the geothermal reservoir outlined by dashed black lines, Fig. 15) with gas-rich fluid overpressure from multiple fracture sets (i.e., by convection and advection processes; blue and red arrows in Fig. 15), which are heated by magmatic bodies. These zones are delineated approximately by means of the density of established anisotropy pathway (i.e., stations TV01, TV11, and TV18, Figs. 7 and 8) at depths between 2.0 and 5.0 km and from 2.0 to 5.0 km in the case of data registered at stations TV11 and TV18. Nonetheless, on the other hand, low fracturing could also be considered (e.g., low anisotropy values and normalized delay times, Figs. 5b and 14) due to small confining pressures (e.g., Piccinini and Saccorotti 2018); while in deeper areas, it could be related to over-pressurized hydraulic compartments with pore fluids undispersed (Crampin and Leary 1993). Furthermore, at several depths, due to chemical processes, there would be the existence of sealed fractures (e.g., see black arrows above 3 km, Fig. 15).
For seismic sources events recorded at stations TV03, TV01, TV18, and TV11 at respective depths below levels of 4.0, 5.0, and 6.0 km, not only NW–SE fast directions are observed, but also orthogonal fast directions for seismic sources in spatial ranges constrained as similarly to previous works (e.g., Piccinini and Saccorotti 2018). These effects are particularly observed in proximity of the La Reforma and El Volcan faults. Both fault systems comprise important pathways for the up flow of magmatic fluids from depth. These orthogonal polarizations could evidence the presence of heavily fractured rocks at critically high pore-fluid pressures (e.g., Crampin and Zatsepin 1997) generated by geothermal operations, hydrothermalism (e.g., Pinel and Jaupart 2003; Muirhead et al. 2015), or magmatic fluxes (e.g., Nowacky et al. 2018) (see the areas with the dashed red lines and the distribution of the red arrows, Fig. 15), phenomena that can give rise to differential stresses.
These different saturated fluid contents, sealed fracture effects, and magmatic intrusions occur at the upper part of the granitic basement (the PRB geological unit, Fig. 8a) and reach superficial zones, crossing mainly shallow units (e.g., the SL-SF, EB, Ag, LVdld, Pdld, and UVdld units). The concurrence of these phenomena is related to volcanic environment along with geothermal phenomena that have potential to provide geothermal energy in zones with high fracture densities (e.g., anisotropic pathways delineating conical shapes due to the different arrival angles with vertices at stations, Figs. 7 and 8), which affect the different lithological units. This appears to be mainly located in and around the volcanic zones (see Fig. 11). When these volcanic phenomena and geothermal processes act under a state of continuous stress, they may generate deformation cycles in and around the TVVC area. For instance, NE–SW and N–S secondary fracture sets with different orientations to the pre-existing NW–SE fault structures parallel or sub-parallel orientation to the Gulf of California opening (i.e., the main regional horizontal stress field σH, Chacón-Hernández et al. 2021a, b) could be created, with damage in the rock volume associated with these structures. At shallower depths, high fracturing zones (i.e., large A values associated) indicate structural weakness and would allow generating surface deformations easily, with pre-existing structures controlling the hydrothermal systems as could be occurring around the TVVC area and in other areas (e.g., at the Aluto Volcano, Nowacky et al. 2018). However, at greater depths (e.g., > 5.0 km), as any NW–SE fractures would need to be held open by fluids at high pore-fluid pressures, even away from the geothermal system, the main deformation could be related to strong overpressure fluids linked to magmatic fluids. Thus, if multiple fracture sets are present in the presence of a regional stress field, only one set would be held open. Therefore, over-pressurized fluids are present beneath the volcanic complex, and the overpressure is sufficient to hold open both fracture sets (e.g., secondary directions in rose diagrams, Fig. 13).
Conclusions
The main contributions to the characterization of some zones in the TVVC area are:
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(1)
Shear-wave splitting delays and the anisotropy percentage provided information about the highest fractured zones and their most important anisotropic pathways, which delineate conical shapes with vertices at the stations TV01, TV04, TV11, and TV18. These conical shapes delimit portions of important volumes of fractured rocks, which are mainly located in the volcanic region between EVV and EAV, and toward the La Reforma, El Azufre, El Volcán, EPO, EV1, and EV2 faults. They intersect between stations TV01 and TV18, with a depth range from approximately 2.0 to 5.0 km and with a horizontal extension of approximately 2.5 km between both stations. Likewise, anisotropic pathways intersect between stations TV11 and TV18, with a range from approximately 2.0 to 5.0 km in depth and with an extension of approximately 2.5 km in a straight line between both stations. These zones represent important permeable-fractured zones and can be considered to expand the geothermal exploitation of the geothermal resources, strengthening the analyses of previous studies (e.g., hydrothermal characterization, Romo-Jones et al. 2018; evaluation of geothermal potential, Tello-López and Torres-Rodríguez 2015; fluid inclusion in fractured rocks (temperatures higher than 240 °C at depths between 1.5 and 2.5 km in the TVVC), Romo-Jones et al. 2000; Wong et al. 2001) and helping to describe the existence of new permeable rock volumes. Additionally, some other external areas with high fracturing are also observed near the LVV volcano and toward the La Virgen-El Campamento, El Volcán, and El Mezquital faults. These high fracturing zones reached the upper part of the PRB geological basement whose top has been observed at a depth of 1.13 km below the surface (Garduño-Monroy et al. 1993), and it includes the shallowest geological units (SL-SF, EB, Ag, LVdld, Pdld, and UVdld among others), where the geothermal reservoir has been considered to be located at depths of around 1.5 km.
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(2)
The selection of seismic events near stations (i.e., < 0.035° in latitude and longitude) and restricted to specific areas with incident angles less than 45°, enabled to assure as much as possible homogeneous conditions of some factors and phenomena that affect the anisotropic signals (i.e., rock and lithology types, fracture orientations, fluid inclusions, magmatic influences, or particular fault systems). This constraint on the data enables us to observe a pervasive anisotropy near the TV01 (i.e., δt n = 31.95 ms/km), TV11 (i.e., δt n = 16.3 ms/km), and TV18 (i.e., δt n = 26.17 ms/km) stations with a hypocentral distance from at least 3.5 and 4.0 km.
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(3)
The relationships observed between values of δt vs. fmax, A vs. Vs, and fmax vs. Vs allow considering the possibility that fracture systems could be affected by different fluid content, steam flow, or that they have been chemically sealed. These circumstances do not seem to constitute a feature of a unique zone and depth, as is evidenced by the different values of each data group GA1, GA2, GA3, GB1, GC1, GC2, and GC3 (see Fig. 11 and Table 5). For instance, larger fluid content could be mostly considered in the 5–6-km depth interval for those data related to station TV11 compared with the 4–5-km depth interval, which is supported by the different fmax and Vs values (e.g., Fig. 12).
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(4)
The analysis of the main fast polarization directions with respect to the different depth ranges of the analyzed seismic events, allowed considering a strong NW–SE regional fracture system reaching a minimal depth of 8.0 km, accompanied by minor NE–SW, NNE–SSW, N–S, or E–W fracture systems which could be representing intersection of fracture systems. In general, it was possible to observe that fracture systems contribute to the anisotropy observed at different depth levels.
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(5)
Noteworthy variations of fast polarizations observed in the rose diagrams, preferentially for those seismic events analyzed deeper than 4–5 km at station TV03, 5–6 km at stations TV01 and TV18, and deeper than 6.0 km at station TV11, indicate fracture systems in other orientations, which could be due to the influence of magmatic bodies, intrusive systems or subvolcanic bodies, whose depths seem to be correlated with those reported in other previous studies. The presence of magmatic bodies could be supported by lower fmax, A, and Vs, values (i.e., groups GB1 and GC1), which seem to be located from the 4.0 km depth (e.g., for the seismic events recorded at station TV01 of the GB1 group, Table 5) but more concentrated from the 5–6 km depth interval and around EVV and EAV. It must be stated that the location of possible magmatic bodies does not necessarily follow a single depth interval with homogeneous effects, but in different places and depths.
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(6)
Our results indicate that anisotropy is being affected by volcanic and geothermal processes, representing multifaceted effects operating throughout different places and depths, where different fluid contents, steam flow, and magmatic bodies could be occurring and interacting at a same depth interval. Likewise, this study evidences a structurally complex and highly fractured area, at least in the zone of EVV and EAV and toward the La Reforma, El Azufre, El Mezquital, El Volcán, EPO, EV1, and EV2 faults, which evolve as volcanic and geothermal processes continue generating changes in the local stress field.
Data availability
Data are available at https://doi.org/https://doi.org/10.17632/765c9t2rtr.1
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Acknowledgements
We acknowledge Gerencia de Proyectos Geotermoeléctricos, Subgerencia de Estudios of the Comisión Federal de Electricidad (CFE), for having provided the seismic and injection–production data CFE, especially to Ing. Cecilia Lorenzo Pulido, Chief Geophysical Discipline, CFE Generation VI, Geothermal Power Projects Management. A graduate scholarship support from CONACyT (FC) is also thankfully acknowledged.
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Chacón-Hernández, F., Campos-Enríquez, J.O., Zúñiga, F.R. et al. Inference of fracturing zones and degrees of fluid content in the Las Tres Virgenes volcanic complex based on an analysis of seismic anisotropy. Acta Geophys. (2024). https://doi.org/10.1007/s11600-024-01327-1
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DOI: https://doi.org/10.1007/s11600-024-01327-1