3.1. Phenomenological characteristics of cyclic injection

We first present the qualitative observations during cyclic injection processes, focusing on the evolution of fluid distribution morphology, saturation, and ganglia size and numbers. Figure 2 shows the invasion morphologies for the first five injection cycles with water contact angle of $60^\circ$. During the first CO$_2$ injection, i.e. drainage process, the CO$_2$ (the non-wetting phase, in orange colour) invades the medium, developing thin fingers with trapping of water, a typical signature of capillary fingering. In the first imbibition, water re-enters the domain, occupying the pore space shown in light blue. Thus, the light-blue area also represents the CO$_2$ that has been displaced out of the domain during the process. We define the active area (or mobile fraction) for a displacement process as the region that has a change of status in phase occupation (orange in drainage, light blue in imbibition). It can be seen that the active area decreases as the cycle number increases (with sequence of injection indicated by black arrows). Also, starting from the first imbibition, the active area can be disconnected, different from a continuous phase as in single-time injection processes. This is due to the re-activation of isolated ganglion when connected to the inlet, allowing jumps of meniscus advancement events. Further, the results indicate that the morphology of the active area tends to converge to the same path as the cycle number increases, regardless of drainage or imbibition.

Figure 2. Invasion morphologies of first five injection cycles with water contact angle $\theta =60^\circ$. Orange represents the newly invaded CO$_2$, which is equivalent to the water that is mobilised during the displacement process. Light blue represents newly invaded water (mobilised CO$_2$). Arrows indicate the sequence.

To more clearly show the evolution of the active area during cyclic injection, the temporal colour-map of the active area is shown in figure 3(a). The pattern of the active area shifts from typical capillary fingering to a less ramified regime, which eventually converges towards a single main flow channel. This behaviour in the mobile region is also observed in recent experiments using a micro-model in the capillary-dominated regime (Ahn et al. Reference Ahn, Kim, Lee and Wang2020). Note that the colour-map in figure 3(a) concerns the first five injection cycles to avoid colour skewness. The change in active area after five cycles is found to be insignificant (supplementary movie 1 is available at https://doi.org/10.1017/jfm.2023.222).

Figure 3. (a) Evolution of the active area during displacement processes. Only the first five cycles are shown to avoid colour-map skewness, as the change in active area is insignificant after five cycles. (b) CO$_2$ saturation $S_\mathrm {CO_2}$ as a function of cycle number. The blue-dotted line with circles marks the residual CO$_2$ saturation $S_{r,\mathrm {CO}_2}$ after water injection. (c) Number of CO$_2$ ganglia. (d) Normalised average CO$_2$ ganglia size. The ganglia size is normalised by the average pore size (red region in the inset). In panels (b–d), red-solid and blue-solid lines correspond to drainage and imbibition processes, respectively.

Figure 3(b) plots the CO$_2$ saturation $S_\mathrm {CO_2}$ during cyclic injection. Red and blue lines, with water contact angle being $60^\circ$, correspond to drainage and imbibition processes, respectively. Clearly, hysteretic behaviour in $S_\mathrm {CO_2}$ is observed with increase/decrease in $S_\mathrm {CO_2}$ during drainage/imbibition. One parameter of significant importance in the context of carbon geosequestration is the residual CO$_2$ saturation $S_{r,\mathrm {CO}_2}$ after water injection, which represents the amount of CO$_2$ that is stably trapped by capillary force and cannot be mobilised by water. The blue-dotted line in figure 3(b) indicates that an increase in $S_{r,\mathrm {CO}_2}$ with number of injection cycle is observed, consistent with existing experimental and numerical observations (Edlmann et al. Reference Edlmann, Hinchliffe, Heinemann, Johnson, Ennis-King and McDermott2019; Ahn et al. Reference Ahn, Kim, Lee and Wang2020; Herring et al. Reference Herring, Sun, Armstrong, Li, McClure and Saadatfar2021). This implies that the CO$_2$ within the porous medium becomes more stable as the number of injection cycles increases, which can be explained by the evolution of CO$_2$ ganglia size and number, as plotted in figures 3(c) and 3(d), respectively. During water injection (imbibition process indicated by blue lines), the CO$_2$ is broken into more ganglia, which is associated with a reduction in the average ganglia size and increase in ganglia number. However, a decrease in ganglia number and increase in average ganglia size are observed during drainage, corresponding to the newly injected CO$_2$ connecting isolated CO$_2$ ganglia during the invasion process. The overall trend of decreasing ganglia size thus leads to the capillary trapping being more stable, which also facilitates subsequent CO$_2$ dissolution into water as a result of greater area-to-volume ratio. Note that the dissolution of CO$_2$ is not accounted for in the algorithm, as the focus in the current study is placed on the fluid displacement processes, i.e. residual saturation trapping as opposed to solubility trapping (Matter & Kelemen Reference Matter and Kelemen2009). It is found that 15 injection cycles are sufficient for the displacement process to reach the equilibrium state, i.e. no further changes in the saturation hysteresis (${\rm \Delta} S_\mathrm {CO_2}$) or ganglia distribution (supplementary movie 1).

The phenomenological characteristics during cyclic injection reported above for ${\theta =60^\circ}$, i.e. the hysteretic behaviour in fluid morphology, saturation and ganglia distribution, are also qualitatively observed with different contact angles. In the following, the impacts of wettability during cyclic injection processes are quantitatively analysed.

3.2. Effects of wettability on the hysteretic saturation of CO$_2$

First, the CO$_2$ saturation after the first CO$_2$ injection $S_{r,\mathrm {CO}_2}^{N=0}$ (after zero injection cycle) is plotted as red line in figure 4(a) with error bars representing the standard deviation of five simulations. Here, $S_{r,\mathrm {CO}_2}^{N=0}$ also represents the sweep efficiency of a single-time displacement process, which has been investigated extensively (Trojer et al. Reference Trojer, Szulczewski and Juanes2015; Jung et al. Reference Jung, Brinkmann, Seemann, Hiller, Sanchez de La Lama and Herminghaus2016; Zhao et al. Reference Zhao, MacMinn and Juanes2016; Singh et al. Reference Singh, Scholl, Brinkmann, Michiel, Scheel, Herminghaus and Seemann2017; Wang et al. Reference Wang, Chauhan, Pereira and Gan2019). The increase in $S_{r,\mathrm {CO}_2}^{N=0}$ as the porous medium becomes more wetting to the invading phase was explained by the favoured pore-scale overlap events (Cieplak & Robbins Reference Cieplak and Robbins1988; Holtzman & Segre Reference Holtzman and Segre2015). Figure 4(a) shows that as the water contact angle increases, i.e. invading phase being more wetting to the porous medium, $S_{r,\mathrm {CO}_2}^{N=0}$ increases, consistent with past observations (Jung et al. Reference Jung, Brinkmann, Seemann, Hiller, Sanchez de La Lama and Herminghaus2016; Wang et al. Reference Wang, Chauhan, Pereira and Gan2019, Reference Wang, Pereira, Sauret, Aryana, Shi and Gan2022a). Particularly, as the contact angle increases to $\theta =135^\circ$, i.e. in CO$_2$-wet porous media, a compact CO$_2$ invasion with almost 100 % CO$_2$ saturation is observed.

Figure 4. (a) CO$_2$ saturation as a function of contact angle after: (i) the first CO$_2$ injection, $S_{r,\mathrm {CO}_2}^{N=0}$ (red); (ii) the first water injection, $S_{r,\mathrm {CO}_2}^{N=1}$ (blue); and (iii) 15th water injection, $S_{r,\mathrm {CO}_2}^{N=15}$ (black). Error bars represent the standard deviation. (b) Difference in saturation between $S_{r,\mathrm {CO}_2}^{N=0}$ (red) and $S_{r,\mathrm {CO}_2}^{N=15}$, which quantifies the ultimate CO$_2$ saturation reduction due to cyclic injection.

Then, we plot the residual CO$_2$ saturation after the first water injection process, $S_{r,\mathrm {CO}_2}^{N=1}$, marking the completion of the first cycle. As shown by the blue line in figure 4(a), a significant decrease in CO$_2$ saturation can be observed after the water flooding for all wetting conditions, with more significant decrease in CO$_2$ for greater $\theta$. After 15 cycles, the residual CO$_2$ saturation $S_{r,\mathrm {CO}_2}^{N=15}$, which represents the maximum CO$_2$ saturation after sufficient numbers of cyclic injections, is shown as a black line. Compared with the residual saturation after only one cycle (blue line), a consistent improvement in CO$_2$ saturation can be seen, revealing the favourable effect of cyclic injection for enhancing capillary trapping of CO$_2$. Further, the results also indicate that at an equilibrium state, either water-wet or CO$_2$-wet porous media are better at trapping CO$_2$ compared with weakly water-wet or neutral ones. However, in the context of enhanced oil recovery, these results imply that the neutral wetting condition is ideal compared to either oil-wet or water-wet ones for achieving lowest residual oil saturation, which is consistent with experimental observation in the literature (AlRatrout, Blunt & Bijeljic Reference AlRatrout, Blunt and Bijeljic2018). It is found that the boundary effect enhances CO$_2$ trapping near the solid walls for CO$_2$-wet porous media and suppresses CO$_2$ trapping for water-wet ones (figure 9a). However, the impacts from the boundary are insignificant and do not influence the conclusion from the results (see Appendix A).

The overall variation in CO$_2$ saturation under different wetting conditions is quantified by the difference between $S_{r,\mathrm {CO}_2}^{N=0}$ and $S_{r,\mathrm {CO}_2}^{N=15}$ in figure 4(b), where an increasing trend can be observed. The insets show the CO$_2$ (white) and water (blue) distribution after the first CO$_2$ injection (left) and after 15 injection cycles (right) for a water-wet case ($\theta =45^\circ$) and a CO$_2$-wet case ($\theta =135^\circ$), respectively. Under the water-wet condition, the initial injection of CO$_2$ corresponds to a drainage process, where the invasion morphology falls into the capillary fingering regime described by the theory of invasion percolation (Wilkinson & Willemsen Reference Wilkinson and Willemsen1983; Lenormand & Zarcone Reference Lenormand and Zarcone1985). The resulting CO$_2$ ganglia tend to reside in relatively large pore spaces, which can be easily trapped during subsequent water flooding processes, thus becoming difficult to mobilise. However, compact distribution of CO$_2$ after the first injection can be seen when $\theta =135^\circ$, which is expected due to more pore-scale cooperative pore-filling events (Cieplak & Robbins Reference Cieplak and Robbins1988; Holtzman & Segre Reference Holtzman and Segre2015), resulting in a displacement efficiency close to 1. Nevertheless, a significant amount of CO$_2$ can be mobilised during subsequent water flooding processes, dramatically reducing the residual CO$_2$ saturation in the porous media, which is associated with the large value of ($S_{r,\mathrm {CO}_2}^{N=0}-S_{r,\mathrm {CO}_2}^{N=15}$). In summary, although a CO$_2$-wet porous medium can have larger capacity in storing CO$_2$ during the first CO$_2$ injection, a significant amount of CO$_2$ is unstable and can be mobilised by subsequent underground water flow, increasing the risk of leakage and leading to a reduced storage capacity of the geological formation.

Another common approach to represent the hysteretic behaviour during cyclic injection is through the capillary pressure-saturation curves. The dimensionless capillary pressure is calculated by $P^*_c=1/r^*$, where $r^*$ is the dimensionless meniscus radius. Due to the relatively uniform grain size distribution in the absence of gravity, the capillary pressure signal is found to be flat (figure 10). For the ease of visualisation, the capillary pressure is converted by constraining a positive increment in $P_c^*$, such that $P_c^*$ monotonically increases with the invading phase saturation (see Appendix B). Figure 5 shows the history of pressure-saturation relation (averaged from five simulations) during the first five injection cycles for contact angles $\theta =\{45^\circ,90^\circ,135^\circ \}.$ The increase in the cycle number is denoted by the arrow direction as well as the increasing colour intensity. In water-wet porous media ($\theta =45^\circ$), it can be seen that the decrease in CO$_2$ saturation hysteresis during the drainage–imbibition cycles is mainly due to the increase in the residual CO$_2$ saturation after water flooding, implying that a significant amount of CO$_2$ is broken up by injected water into smaller blobs during the imbibition process, which leads to more stable capillary trapping. For CO$_2$-wet porous media ($\theta =135^\circ$), in contrast, the decrease in saturation hysteresis results from the decrease in CO$_2$ saturation after CO$_2$ injection. This is associated with an increasing amount of water being stably trapped within the porous media, reducing the pore space available to CO$_2$. For neutral-wet porous media, the saturation hysteresis decreases during both water injection and CO$_2$ injection, which is reflected by the relatively symmetrical narrowing of saturation towards the middle. In all plots, it can be seen that the change in $P^*_c$ is not significant during the injection process due to relatively uniform pore size distribution (20 % variation in particle size). Also, vertical jumps in $P^*_c$ can be observed between each injection process, indicating a sudden shift in the wettability of the invading fluid at the inlet. Note that the pressure scale in the $y$-axis for neutral-wet porous media is much smaller, which is expected as both water and CO$_2$ in this case have the same contact angle $\theta =90^\circ$.

Figure 5. Capillary pressure versus CO$_2$ saturation curves for the first five cycles with contact angles $\theta =\{45^\circ,90^\circ,135^\circ \}$ (from left to right). Brown and blue colours respectively represent the CO$_2$ and water injections. Dashed arrows as well as the increasing colour intensity indicate the increasing cycle number.

To evaluate how the saturation hysteresis ${\rm \Delta} S_\mathrm {CO_2}$ evolves during cyclic injection, figure 6(a) plots ${\rm \Delta} S_\mathrm {CO_2}$ against the number of injection cycles with the experimental data from Ahn et al. (Reference Ahn, Kim, Lee and Wang2020) added for comparison. It is found that the data can be described by the following exponential decay:

(3.1)\begin{equation} {\rm \Delta} S_\mathrm{CO_2}=(S^{N=0}_{r,\mathrm{CO}_2}- {\rm \Delta} S^*_\mathrm{CO_2})\cdot a^{{-}N}+{\rm \Delta} S^*_\mathrm{CO_2},\end{equation}

with $N$ the number of cycles, $a$ a fitting parameter, $S^{N=0}_{r,\mathrm {CO}_2}$ the initial CO$_2$ saturation after the first CO$_2$ injection and ${\rm \Delta} S^*_\mathrm {CO_2}={\rm \Delta} S^{N=15}_\mathrm {CO_2}$ the saturation hysteresis after a sufficient number of cycles (15 in this study) for the system to reach equilibrium, i.e. the terminal/equilibrium saturation hysteresis. The fitted curves are plotted as solid lines in figure 6(a); they can well capture the evolution of ${\rm \Delta} S_\mathrm {CO_2}$. It is found that there is not a significant dependence of $a$, the decay rate of saturation hysteresis, on contact angles (figure 6b). It is likely that the value of $a$ depends on factors such as connectivity of pore space and particle shape, which is worth investigating in a future study.

Figure 6. (a) Evolution of CO$_2$ saturation hysteresis ${\rm \Delta} S_\mathrm {CO_2}$ with number of injection cycles $N$ for different contact angles. Solid curves are from (3.1). (b) Fitting parameter $a$ in (3.1) as a function of contact angle. Error bars represent standard deviation.

We then plot the initial and residual CO$_2$ saturation over the course of 15 cyclic injections in figure 7 to compare with the classic trapping model by Land (Reference Land1968). Data from two recent experimental works on cyclic injection are also added (Ahn et al. Reference Ahn, Kim, Lee and Wang2020; Herring et al. Reference Herring, Sun, Armstrong, Li, McClure and Saadatfar2021). The direction of increasing cycles are marked by dashed arrows. The movement in the initial-residual CO$_2$ saturation map represents the evolution of saturation hysteresis during cyclic injections. It can be seen that the trajectories from both the current work and literature do not strictly follow the Land model, i.e. $S_{r}=S_{i}/(1+CS_{i})$ (Land Reference Land1968) (black-solid curves). However, one common feature is that they all travel towards a direction with decreasing $C$, which is associated with smaller changes in saturation after water flooding. This can be graphically represented by the decrease in the distance with the black-dashed line (zero hysteresis). Further, the stabilisation/convergence of the trajectories towards a certain point provides evidence that the system has reached the hysteresis equilibrium, i.e. the variation in CO$_2$ saturation between injection cycles becomes constant and does not further change as injection cycle increases. This is however not captured in the past experimental data due to a limited number of injection cycles.

Figure 7. Evolution of initial and residual CO$_2$ saturation during cyclic injections for different contact angles. Dashed arrows indicate the direction of increasing cycles for $\theta =\{45^\circ,90^\circ,135^\circ \}$. Black-solid curves correspond to the Land model with parameter $C=\{0.4,2\}$.

3.3. Terminal saturation hysteresis

It can be seen in figures 5 and 6(a) that the hysteresis in saturation does not further change after a sufficient number of cycles, i.e. when the quasi-static cyclic injection processes reach the equilibrium. The non-zero residual hysteresis in saturation ${\rm \Delta} S^*_\mathrm {CO_2}={\rm \Delta} S^{N=15}_\mathrm {CO_2}$, or the terminal saturation hysteresis, highlights the history dependence of the quasi-static fluid displacement processes, in line with recent experimental work (Holtzman et al. Reference Holtzman, Dentz, Planet and Ortín2020). The terminal saturation hysteresis ${\rm \Delta} S^*_\mathrm {CO_2}$ as a function of contact angle is plotted in figure 8. The ${\rm \Delta} S^*_\mathrm {CO_2}$ also represents the converged active area, which is shown in the insets of figure 8 for sample cases with $\theta =\{45^\circ,90^\circ \,135^\circ \}$. It can be seen that ${\rm \Delta} S^*_\mathrm {CO_2}$ increases with contact angle, reaching the peak values at neutral-wet porous media which is associated with the formation of several loops in the active area, before dropping as $\theta$ further increases. The interesting symmetry in ${\rm \Delta} S^*_\mathrm {CO_2}$ can be explained by the symmetrical wettability during cyclic injection, where the contact angle is reversed between cycles. The greater saturation hysteresis, or active area as shown in the insets, under neutral-wet condition is consistent with a recent study where a higher relative permeability is found in neutral-wet porous media compared to water-wet ones (Hashemi, Blunt & Hajibeygi Reference Hashemi, Blunt and Hajibeygi2021).

Figure 8. Terminal saturation hysteresis ${\rm \Delta} S_\mathrm {CO_2}^*$ for different contact angles. Error bars represent standard deviation. Insets show examples of the active area during cyclic injections for contact angles $\theta =\{45^\circ \,90^\circ, 135^\circ \}$.

To interpret the hysteresis during immiscible fluid displacement in porous media, a discrete-domain model was recently proposed by Cueto-Felgueroso & Juanes (Reference Cueto-Felgueroso and Juanes2016) where each sub-domain (REV) of the porous media is represented by a capillary tube whose diameter varies non-monotonically with the axial position, such that the pressure-saturation relationship is also non-monotonic. According to the model, the macroscopically observed hysteresis is a result of the collective behaviour of these interconnected multistable capillary tubes. Thus, the magnitude of the hysteresis should depend on the local energy barrier of the capillary tube when transitioning across different local minima of the Gibbs-like free energy. In the case (current work) of porous media of pore structures with statistically fixed geometrical features, i.e. fixed fluctuations in the pore/throat sizes, the fluid–fluid interfaces in either water-wet ($\theta <90^\circ$) or CO$_2$-wet ($\theta >90^\circ$) will be associated with greater absolute capillary pressure compared with neutral-wet media ($\theta \sim 90^\circ$), assuming $P_c^*\propto 1/\cos {\theta }$ in capillary tubes (Blunt Reference Blunt2017). This implies that the associated energy barrier between different meta-stable states is also magnified, making the menisci more stable and less likely to be mobilised, consequently leading to less saturation hysteresis between injection cycles, in line with our results in figure 8.

In this work, we have investigated the trapping of immiscible fluids during cyclic injections in the quasi-static regime. In the context of carbon geosequestration, our focus has been placed on investigating the residual saturation trapping mechanism (capillary trapping). We want to point out that if other factors such as viscosity, dissolution or wettability alteration are taken into account, different behaviours in the saturation hysteresis may be expected. It has been established that the trapped phase can be mobilised via momentum transfer (Zarikos et al. Reference Zarikos, Terzis, Hassanizadeh and Weigand2018) and mechanisms such as droplet fragmentation can occur under high viscous stress (Pak et al. Reference Pak, Butler, Geiger, van Dijke and Sorbie2015). Furthermore, variations in solid surface wetting condition are possible due to long-term exposure to the non-wetting phase, high temperature or pressure (Chiquet, Broseta & Thibeau Reference Chiquet, Broseta and Thibeau2007; Kim et al. Reference Kim, Wan, Kneafsey and Tokunaga2012; Wan, Kim & Tokunaga Reference Wan, Kim and Tokunaga2014), which may affect the subsequent displacement processes during cyclic injections. In addition, the heterogeneity of the porous media in the current work is mainly from the variations in particle size. Other forms of heterogeneity, such as wettability (Zhao et al. Reference Zhao, Kang, Yao, Viswanathan, Pawar, Zhang and Sun2018; Jahanbakhsh, Shahrokhi & Maroto-Valer Reference Jahanbakhsh, Shahrokhi and Maroto-Valer2021; Irannezhad et al. Reference Irannezhad, Primkulov, Juanes and Zhao2023), grain shape (Rokhforouz & Akhlaghi Amiri Reference Rokhforouz and Akhlaghi Amiri2019; Wang et al. Reference Wang, Pereira and Gan2021) and surface roughness (Tanino, Ibekwe & Pokrajac Reference Tanino, Ibekwe and Pokrajac2020; Wang, Pereira & Gan Reference Wang, Pereira and Gan2020; Zulfiqar et al. Reference Zulfiqar, Vogel, Ding, Golmohammadi, Küchler, Reuter and Geistlinger2020), can also impact the immiscible fluid displacement processes and residual trapping. The results from the current work should lay the foundation for future investigations on the influence of these complexities during cyclic injections.