The influence of alteration and fractures on gas permeability and mechanical properties of the sedimentary and volcanic rocks of the Acoculco Caldera Complex (México)

This group is represented by Acb2, Ac66, Ac264, and Ac265 samples. They are slightly altered with gray color. It presents a porphyritic texture with plagioclase (from 0.05 to 0.1 mm in size), quartz, amphibole, oxides, chlorite, and epidote in minor proportions. The Ac66 sample presents fractures and pores filled by oxides; its groundmass is made by oriented phenocrysts of albite (Fig. 2a).

This group is represented by Ac31, Ac50, and Acb10 samples. They are a very altered white sample and slightly gray and yellow stained. Samples are very fractured with an aphanitic recrystallized amorphous silica texture (vuggy silica), and interconnected pores and fractures (Fig. 2b). The groundmass is almost all recrystallized, composed predominantly of glass and amorphous silica; phenocryst shapes are hardly recognizable. According to X-ray powder diffraction, the major constituents of samples are quartz (from ~60 to ~65 %) and cristobalite (from ~30 to ~35 %), and some samples, including Ac50 and Acb10, could be constituted also by sanidine and albite in minor proportion (<5 %). SEM-EDS analysis also identifies the content of iron, sulfur, barium, and zircon (<2 %) (Fig. 2c). Ac50 and Acb10 samples present a not clear porphyritic texture, composed predominantly of phenocrysts of feldspar, pyroxene, quartz, epidote, oxides, and pores filled by oxides (Fig. 2d), with sinuous fractures (from 2 to 50 μm in aperture) filled by fine-grained material (Fig. 2e). Despite the high degree of alteration in sample Acb10 some minerals such as plagioclase (from 0.8 to 1 mm in size), biotite (from 0.05 to 0.1 mm in size), amphibole, and quartz are recognizable.

This group is represented by AcPc, Acb3, Acp2, and Acb7 samples. They are gray with observable veins and fractures, sub-perpendicular to the lamination (60 to 70° with respect to the lamination axis), some of which are filled with carbonate and some others converge with each other. Thin sections description showed, in all the samples, a matrix-supported texture, the presence of ellipsoidal carbonate grains (from 5 to 100 μm in size), stylolites displacing refilled fractures, and bioclast (gastropods) in minor proportion (from 1 to ~10% for Acb7 sample) (Fig. 2f, g). Particularly, sample Acb7 exhibits a dominant characteristic in terms of secondary structure: it shows fractures cutting the grains and some opaque minerals with hexagonal and cubic shapes (Fig. 2h) and throat and chamber fractures type.

The mean measured values of porosity (effective and total) and permeability of volcanic and sedimentary rocks are presented in Table 1. Limestone showed homogeneous values for the petrophysical parameters. Total porosity values range from 8.37 ± 0.29 to 11.76 ± 0.12 %. Effective porosity values (determined through Helium pycnometry and Mercury intrusion techniques) range from 0.76 ± 0.10 to 1.37 ± 0.62 % and 0.18 ± 0.07 to 0.44 ± ˂0.01%, respectively. In contrast, volcanic samples showed significant heterogeneity. For example, the total porosity of the unit Ac50 (high alteration grade) was 50.79 ± 3.50%, and effective porosity of 49.21 ± 3.54% using Helium pycnometry. On the other hand, Acb2 (fresh rock) has a total porosity of 6.35 ± 0.82% and effective porosity of 1.97 ± 1.15%. Figure 3 a displays the throat pore size diameter distribution determined through Hg-porosimetry of each rock specimen. In general, limestone specimens have a homogenous pore throat ranging from 15 to 90 μm (f1), and only one exception in specimen Acb7-01 which presents two distinct populations, ranging from ~0.01 to 2 (f1) and from ~15 to 90 μm (f2). On the other hand, hydrothermal altered volcanic rocks show two distinct populations, ranging from ~0.010 to 2 (f1) and from ~11 to 80 μm (f2) (Fig. 3a). The interpretation of results from Mercury intrusion in volcanic rocks, particularly in altered units must consider an extra aspect. The measurement rate of this technique is limited to pores between 0.001 and 100 μm diameter. Therefore, some pores in the altered samples (> 10 mm) did not account for the measurements. This phenomenon explains the different effective porosity values obtained from Mercury intrusion and Helium pycnometry (range of measurements from 0.05 to 10,000 μm) for the same rock specimen (Acb10, Ac31, Ac50) (Table 1). The above situation also should be considered for the calculation of the flow regime (K_n). The calculated K_n for volcanic altered samples was > 10. According to Ziarani and Aguilera (2012), corrections due to diffusion and slippage should be applied to the permeability values. However, the Mercury intrusion results do not show all the spectra of pore sizes, and only corrections for slippage effects (Klinkenber and Forchheimer correction) were applied to permeability values.

Permeability values measured on limestone specimens are generally low, with no significant variations observed. Permeability rated from ≤ 9.87×10⁻¹⁹ m² (the lower acquisition limit of the device) to 3.5×10⁻¹⁸ m² (Table 1). These values are perfectly in accordance with the low effective porosity values (η_e ˂ 1.37%) and it is similar to the values from the same area (Weydt et al. 2018, 2021). As well as porosity values, permeability values on volcanic specimens show high variability, dependent on the alteration degree. It rates from a maximum value of 2.6×10⁻¹² m² to a minimum value of 1.3×10⁻¹⁸ m², from hydrothermally altered (Ac31) to fresh to slightly altered samples (Ac66), respectively. To put our data into a global context, the permeability values of volcanic rocks were compared with values of similar rocks published previously (Fig. 4a) (Farquharson et al. 2015; Heap and Kennedy 2016; Lamur et al. 2017; Colombier et al. 2017; Weydt et al. 2018, 2021; Mordensky et al. 2018). Figure 4a illustrates the relationship between effective porosity and permeability. As the trend line shows, there is a significant exponential relationship with an R²=0.65 of our data, like those established by different authors of similar rocks (e.g., Lamur et al. 2017; Colombier et al. 2017; Heap et al. 2018).

The permeability values of the analyzed hydrothermally altered rhyolite specimens (Ac31 and Acb10) are in good accordance with the values of effusive rhyolites reported by Colombier et al. (2017). In contrast,the hydrothermally altered andesite samples, despite having similar effective porosity values, exhibit lower permeability, especially in the most altered unit (Ac50), which does not align with those reported by the same author. As expected, the grade of hydrothermal alteration in volcanic samples influences the relationship between properties. Particularly, the distribution of data included in Fig. 4a indicates that the porosity and permeability values increase with the increase in the degree of alteration. On the contrary, some data does not fit in this general trend, showing higher permeability values. For example, Ac50 and Ac31 samples exhibit similar values of effective porosity, but Ac31 has higher permeability. This difference in permeability is attributed to the intrinsic characteristics of the pore system, such as pore size, geometry, and spatial distribution.

At the reservoir scale, our results suggest that the poor porosity and low matrix permeability values of the limestone unit function as a barrier for fluid circulation from top to bottom. On the contrary, porosity and permeability values obtained for volcanic units suggest that these units allow fluid circulation, evidenced by the observed alterations of the different collected units. The origin of the fluids affecting the volcanic units is not included in this work (for detailed information consult Pandarinath et al. 2020). However, based on the porosity characteristics of limestone and volcanic units, it can be assumed that hydrothermal fluids are not affecting the limestone unit. Even when the thickness of the volcanic units can reach up to 800 m (Avellán et al. 2019, 2020; Guerrero-Martínez et al. 2020; Viggiano-Guerra et al. 2011), the temperature gradient is not sufficient to consider them as a potential target for exploitation (100°C). On the contrary, at depths of 2000 m, where the limestone unit is located, the temperature rises to 300 °C (measured temperature in wells EAC-1 and EAC-2, Guerrero-Martínez et al. 2020). This temperature is more than sufficient for geothermal exploitation; however, fluid circulation is poor or null, as shown in our results. Thus, as well described in previous investigations (Deb et al. 2020; López-Hernández et al. 2009), the ACC is a good candidate for using stimulation techniques such as hydraulic fracturing.

Table 1 displays the UCS values for both volcanic and limestone specimens. Figure 5a and b show the stress-strain relationship of limestones and hydrothermally altered volcanic samples, respectively. UCS values of limestones range from 88.32 to 150.96 MPa, while for hydrothermal altered volcanic samples range from 3.12 to 31.86 MPa (Fig. 5b). The influence of the intensity of hydrothermal alteration on the strength values is evident if we compare them with the values of fresh to slightly altered samples, where there are values greater than 150 MPa. In addition, as shown in Fig. 4 b, the strength values decrease by an increment of both the percentage of total porosity and the pore size due to the hydrothermal alteration processes. Particularly, the strength reduction related to porosity is due to both (García-del-Cura et al. 2011; Baud et al. 2014): (1) the distribution and pore geometry cause a reduction of the load sample section; and (2) the pores act as stress concentration points, being the strength lower as the pore diameter increase (Heap and Kennedy 2016; Davis et al. 2017; Avar and Hudyma 2022), this is evident in the Ac31 sample, where pores of centimetric measurements and vuggy texture were recognized. On the other hand, the strength values variability in limestones is due to the presence of discontinuities as stylolites in every single specimen, as well as their characteristics, including thickness, filling, previous displacement, orientation with respect to the load axis, and in the case that the specimen contains two or more discontinuities it will also depend on their geometrical arrangement, persistence, and their nature of termination, including horizontally and vertically intersecting fracture. For example, the content of parallel and subparallel discontinuities in each group, is responsible for the reduction of the maximum strength, for sample: AcP2 the strength varies from 182 to 78 MPa, which represents a decrease of more than 50% and it is the same scenario for more homogeneous specimens, including samples Acb7 and Acb3 (Fig. 5a, c). On the contrary, several specimens from the AcPc rock sample show the lowest value of strength basically because of the presence of sub-perpendicular fractures to the load axis (Fig. 5a, c). Particularly, the AcPc-04 specimen shows the lowest strength value, because of the presence of at least four types of discontinuities, including intact bedding planes, incipient, stylolites and refilled (see Fig. 5a, c). Limestones, fresh to slightly altered and altered volcanics show different stress-strain patterns as well as different failure modes (Fig. 5a, b, c). In general terms, the failure mode of low porosity limestones and fresh to slightly altered volcanics is brittle, while hydrothermally altered samples tend to be more ductile due to an increase in porosity. As graphically described in Fig. 5 a and b, sudden stress decreases in the stress-strain curves could be associated with small displacement into the plane of discontinuities and to the coalescence of macropores, for limestones and altered volcanic samples, respectively. Particularly, the hydrothermally altered volcanic samples, including Ac31 and Ac66, after the initial failure, do not completely break apart (Fig. 5b).

A total of 60 specimens (26-mm diameter) were fractured by a point load test and tested for fracture permeability (K_f). The effective porosity after fracturing (η_ef) was calculated using Eq. (5). Table 2 shows these two values and the increment of effective porosity after fracture induction (∆η_e=η_ef - η_e). In general, all the tested specimens showed an increase in the effective porosity due to the fracture. A maximum increase of 2.24% and a minimum of 0.19% were calculated for volcanic samples. For limestones, a maximum increase of 1.85% and a minimum of 0.02% were registered. For all the specimens, fracture permeability showed higher values than the initial matrix permeability. For volcanic specimens, a maximum increase value of 1.61×10⁻¹³ m² and a minimum of 4.14×10⁻¹⁵ m² were measured. For limestone, a maximum increase value of 2.98×10⁻¹⁴ m² and a minimum of 1.61x10^-16 m² were measured (Table 2). Figure 6 shows the exponential relationship between the increment of effective porosity after fracturing (Δη_e) and fracture permeability (K_L) for volcanic (Fig. 6a) and limestone (Fig. 6b) rocks. Previous investigations on fracture permeability using a similar methodology (e.g., Lamur et al. 2017; Kushnir et al. 2018) found the same tendency of increase. The low resulting R² in the equations can be explained by the generated asperities during the fracturing. The higher increases in permeability values in volcanic samples are linked not only to the grain size as established by Lamur et al. (2017) but also to the pore size. The higher the pore size the higher the fracture permeability.

To measure the relative effect of the measured petrophysical parameters in the fracture permeability, a multiple linear regression analysis was implemented. The model that better represents the phenomena includes the total porosity (η_T), effective porosity (η_e), and effective porosity after fracture (η_ef) as independent variables. The dependent variable (fracture permeability) is converted by the Log10 function to obtain a normal distribution. The resulting model is represented by Eq. (6). The model has a corrected R² factor of 0.60 and a p-value of 3.3×10⁻⁴. In other words, 60% of the variations of the model are very well explained by the independent variables (p-value ≤ 0.001). The model is statistically significant.

The model can be used to predict the fracture permeability in similar rocks with mechanically induced fractures. The use of Eq. (5) to calculate the increase of effective porosity after fracturing is an easy alternative to quantify the fracture permeability. During the fracture induction process, small rock fragments were removed from the ridges of the specimen. These fragments, which do not belong to the fracture, make no contribution to the fracture permeability. Excluding this material from Eq. (5) can enhance the model accuracy.

Tiab and Donaldson (2016) highlighted the importance of grain size in the relationships between porosity and permeability, as observed in the distribution of the measured values (Fig. 4a). Specimens with a visibly finer and homogeneous grain size (limestones and fresh volcanic units) tend to be grouped in one zone of the graph. On the other hand, altered volcanic samples with a clearly coarser grain size and a non-homogeneous distribution tend to spread in a wider area. This tendency is not exclusively related to grain size, as defined by the previous authors. It can be observed in the pore size distribution results (Fig. 3a, b) that specimens with homogeneous pore systems (limestone units and the Ac66 unit) show fewer variations during permeability measurements than specimens with a wider pore size distribution (volcanic altered samples). This tendency was observed not only during matrix permeability measurements but also in fracture permeability.

As mentioned, one of the limitations of using mercury intrusion is the coverage range of the method. Other investigations in the characterization of grain size and pore systems have included micro-CT scans (Fusi and Martinez-Martinez 2013; Reedy 2022) and fracture surface scans (Blöcher et al. 2019; Chuyen et al. 2023). One of the main limitations of micro-CT scans is the size of the samples. To obtain high-resolution images, the size of the plugs is limited to a few centimeters and inducing fractures can be a challenging task. Fracture scanning includes important features of the fracture walls (rugosity, tortuosity). Nevertheless, the analysis requires more sophisticated data manipulation and interpretation.

Since the proposed methodology includes a basic petrophysical characterization of rocks, a wide range of experiments can be conducted in the area to achieve a better characterization of all the rock units. The experiments used for this work can be applied to other zones; however, it is essential to consider the singularities of each zone and design the experiments accordingly. The presented results can serve as a first approximation to predict the evolution of permeability and can be included in extensive databases to feed numerical models in the area.

The different properties, including microstructure (e.g., effective porosity, pore type, and pore throats), together with textural properties (e.g., particle size, shape, spatial orientation), and grain-size parameters, greatly control certain mechanisms of fluid transport through the rock matrix and the fracture network (e.g., diffusion, dispersion). Diffusion is referred to as random movements of the molecules and is not controlled by fluid flow. It is barely related to flow over long distances or with fluid-flow velocities. In porous media, three distinct diffusion mechanisms exist, including Knudsen diffusion, which refers to the collision between gas molecules and pore walls (Pan et al. 2010). Besides, dispersion mechanisms result from variations in fluid flow velocity in the rock system, caused mainly by variations in trace lengths, geometry (size, aperture, aspect ratio), orientation, and roughness of boundaries of the interconnected pores and fractures (Zhao et al. 2010).

Observations indicate that the factors influencing diffusion and dispersion mechanisms during permeability measurements resemble those governing gas slippage phenomena in laboratory gas permeability tests. Thus, the intrinsic characteristics of each rock type and the specific attributes of each specimen play a crucial role in determining permeability values. Figure 7 illustrates the gas permeability obtained for each specimen, taking into account the reciprocal mean pressures. For graph interpretation, the following points must be considered: