2.1. Data collection

The high-pressure experiment was carried out at the CRISTAL beamline at the SOLEIL synchrotron and was followed by measurement on an in-house diffractometer with a molybdenum microsource. The same piece of a single crystal of grossular separated from the natural sample was investigated in both experiments. The X-ray diffraction experiments were performed at 293 K with high resolution and completeness (100% completeness up to 0.45 Å).

2.2. Data reduction

Data reduction from all the frames collected was processed using the CrysAlis PRO software (Rigaku Oxford Diffraction, 2015). The reflections inherent to the diamond crystals of the DAC were indexed and omitted in data processing. For each of the two measurements (i.e. synchrotron and laboratory experiments), the resolution of the data was restricted to 0.45 Å to maintain full completeness. Next, the structures were solved and refined with ShelXS (Sheldrick, 2008) and ShelXL (Sheldrick, 2015), respectively, within the Olex2 suite (Dolomanov et al., 2009). Then, the intensities for each of the measurements were merged using Sortav (Blessing, 1995) implemented in the WinGX program suite (Farrugia, 2012). Such merged intensity data were subsequently used as input for the program XD2016 (Volkov et al., 2016). The quality of the hkl datasets obtained is characterized in the supporting information.

2.3. Multipole refinements

The structure of grossular solved and refined at the independent atom model level using SHELX-97 (Sheldrick, 2008) served as a starting point for the refinement of the Hansen–Coppens multipole model. Refinements against the data collected at SOLEIL (herein denoted Exp_1GPa) and the data collected in-house (denoted Exp_Amb) proceeded in the same way. The refinement was conducted on F², and weighting parameters refined by ShelXL were used.

In both cases, the model included a multipole expansion up to the l = 4 level (hexadecapoles). Because Ca, Si and Al atoms occupy special positions, only certain symmetry-allowed multipoles were taken into account. Moreover, special constraints, which allow us to present normalized cubic harmonics as linear combinations of spherical harmonics, were used. Each model was refined in 13 steps. Details of these steps and their order are reported in the supporting information. The scale factor was refined in each step. No significant correlation between the refined parameters was observed.

2.4. Theoretical calculations

Calculations of theoretical electron density distribution were conducted using CRYSTAL17 software (Dovesi et al., 2017, 2018) in which the crystal structure of grossular was optimized. Optimizations of the structure at 1 GPa and at ambient pressure were first realized with the unit-cell parameter fixed at the experimental values (variants 1 and 2, respectively). Three other variants were simulated, for which the structure and the unit-cell parameter were optimized at ambient pressure (variant 3), 1 GPa (variant 4) and 10 GPa (variant 5).

The charge density distributions of these variants were characterized using two different approaches. In the first approach, theoretical dynamic structure factors were calculated with CRYSTAL17 (Erba et al., 2013) and then used to refine a multipolar model of the electron density using the program XD2016, according to the same procedure used in the case of the experimental data. The refinement corresponding to the five structure variants described above will be referred to as theoretical refinement i and labeled TRi (i = 1–5) in the following sections.

In the second approach, topological analysis of the theoretical charge density distributions was performed with the program TOPOND14 (Gatti et al., 1994; Gatti & Casassa, 2013) already implemented in the CRYSTAL17 package.

These theoretical calculation results were used to benchmark both the experimental results obtained from the synchrotron measurement and the in-house diffractometer. Furthermore, they give relevant insights into how properties at bond/interaction critical points (BCPs) depend on the value of the a parameter we used in the different structure optimization variants.

3.1. Crystal structure

Selected details of data collections and refinements are presented in Table 1. Several results from this table deserve closer inspection. Let us mention the different absorption corrections used in both cases. The DAC prevented the use of more advanced absorption correction procedures in the case of synchrotron data collection. Although the unit-cell parameter a determined at 1 GPa appeared slightly larger than expected based on the laws of thermodynamics, it was still within the margin of experimental error (see Fig. 2c). More information about the estimation of the experimental standard deviation for this parameter as well as other details regarding the quality of the measured data are reported in the supporting information.

Figure 2 (a) Unit-cell contents of grossular (Ca: yellow balls, Al: gray balls, Si: orange balls, and O: red balls). (b) Graphical representation of the first-layer AlO6 and SiO4 polyhedra in the grossular crystal structure. (c) The thick horizontal blue bar illustrates confidence intervals (the average value ±3 sample standard deviations) of the parameter a at ambient conditions (the upper line) and 1 GPa (the bottom line). The thin-green vertical bars indicate the average value of the a parameter of ten measurements. The thin red vertical bars indicate the particular values for Exp_Amb (upper part) and Exp_1GPa (lower part).

Grossular, Ca₃Al₂(SiO₃)₄, exhibits a centered cubic symmetry (space group ). It has pseudo-dodecahedral sites (Ca, 24c [Wyckoff notation], 2.22 [site symmetry]), pseudo-octahedral sites (Al, 16a, −3) and pseudo-tetrahedral sites (Si, 24d, −4). Calcium ions are placed at an intersection of three twofold rotation axes, silicon ions at a fourfold rotoinversion point and aluminium ions on a threefold rotoinversion center (see Fig. 2). There is only 1/4 Ca and Si atoms and 1/6 Al atoms in the asymmetric part of the unit cell. Each oxygen atom is bonded to one Si atom, one Al atom and two Ca atoms in a highly distorted tetrahedral configuration. An extensive description of crystal chemistry across the garnet group, including some systematic trends, was given by Antao (2013). The unit cell of grossular is presented in Fig. 2.

3.2. Structural parameters and ADPs

A comparison of interionic distances determined from the experimental and theoretical models is given in Table 2. When one considers the distances obtained experimentally, all the values obtained from data collected at 1 GPa seem to be slightly longer than those obtained at ambient pressure. This is probably caused by the combination of the slightly longer a parameter measured and negligible structural effects exerted by a relatively small 1 GPa applied pressure. However, from a careful comparison of the differences calculated between the experimental values at ambient pressure (Exp_Amb) and the theoretical values at the same pressure (TR3) on the one hand, and the differences observed between the experimental values at 1 GPa (Exp_1GPa) and ambient pressure (Exp_Amb) on the other hand, one can conclude that the slightly higher interatomic distances at 1 GPa, with respect to those at ambient pressure, are meaningless. As demonstrated by the theoretical evolution of these interionic contacts as a function of the applied pressure, one can see that changes in distance are perfectly consistent with the shrinking of the a parameter. Note that a 10 GPa variation (comparison of TR4 and TR5) induces a contraction of the interatomic distances of about 1.5%.

Atomic displacement parameters (ADPs) for the ions forming the grossular structure obtained experimentally are shown in Table 3. ADPs obtained using the theoretical dynamic structure factors are presented in Table S6 of the supporting information.

When we compare the experimental results, with the exception of Al, the ADP values of other ions are larger under 1 GPa pressure (synchrotron measurement) than those obtained for data collected at ambient pressure (in-house diffractometer). For Al the ADPs at 1 GPa are smaller than those for Al at ambient conditions, although all differences are rather small.

Here also, when considering the results obtained by theoretical calculations and the differences between experimental and theoretical values as discussed for the interatomic distances, no significant differences are observed between the 1 GPa and ambient-pressure ADPs values.

3.3. Topology of experimental charge density distribution

One of the most obvious indicators of the similarity between Exp_Amb and Exp_1GPa are properties of the charge density at BCPs. In the case of grossular, we have only three types of interatomic contacts (Ca—O, Al—O, Si—O) and four different BCPs (two different Ca—O contacts).

Information about distances between atoms and BCPs, electron density at BCPs and the corresponding Laplacian for data obtained experimentally as well as results of theoretical calculations are summarized in Table 4. Additional information about experimental data, including the Hessian tensor diagonal values λ_1, λ_2, λ₃ and ellipticity, can be found in Table S4 of the supporting information. The parameters reported in Tables 4 and S4 for the topological analysis of the experimental charge densities at ambient pressure and 1 GPa are in agreement with an expected marginal effect of the pressure for a compound with a room-pressure bulk modulus of about 150 GPa (Hansen & Coppens, 1978).

Table 4 Properties of the charge density ρ(rc) (e Å−3) and the Laplacian ∇2ρ(rc) (e Å−5) at the (3, −1) BCPs of grossular d1-bcp and d2-bcp (Å) denote the distances from the BCP to atoms 1 and 2, respectively. In the case of theoretical refinements (TRi), the left and right values correspond to results from XD2016 and TOPOND14, respectively. X—Y interaction Si—O Al—O Ca—OI† Ca—OII† d1-bcp Exp_Amb 0.694 0.833 1.194 1.273 Exp_1GPa 0.696 0.853 1.191 1.266 TR1 0.705 / 0.685 0.829 / 0.804 1.181 / 1.163 1.257 / 1.234 TR2 0.704 / 0.685 0.827 / 0.803 1.180 / 1.162 1.254 / 1.231 TR3 0.703 / 0.684 0.826 / 0.801 1.178 / 1.160 1.249 / 1.228 TR4 0.703 / 0.684 0.824 / 0.800 1.176 / 1.159 1.246 / 1.225 TR5 0.698 / 0.679 0.815 / 0.792 1.165 / 1.149 1.220 / 1.203 Pyrope 0.692 0.798 0.969 1.039 d2-bcp Exp_Amb 0.953 1.102 1.132 1.244 Exp_1GPa 0.957 1.089 1.143 1.231 TR1 0.955 / 0.974 1.095 / 1.120 1.151 / 1.165 1.237 / 1.257 TR2 0.954 / 0.973 1.093 / 1.117 1.150 / 1.164 1.233 / 1.253 TR3 0.953 / 0.971 1.090 / 1.114 1.148 / 1.162 1.228 / 1.247 TR4 0.951 / 0.970 1.088 / 1.112 1.147 / 1.159 1.224 / 1.243 TR5 0.942 / 0.960 1.070 / 1.093 1.131 / 1.143 1.191 / 1.206 Pyrope 0.943 1.086 1.228 1.294 ρ(rc) Exp_Amb 1.15 0.51 0.19 0.18 Exp_1GPa 1.06 0.53 0.25 0.19 TR1 1.07 / 0.90 0.40 / 0.41 0.29 / 0.28 0.16 / 0.18 TR2 1.07 / 0.91 0.40 / 0.41 0.30 / 0.28 0.16 / 0.18 TR3 1.08 / 0.91 0.41 / 0.41 0.30 / 0.28 0.16 / 0.18 TR4 1.09 / 0.92 0.42 / 0.42 0.30 / 0.28 0.17 / 0.18 TR5 1.12 / 0.95 0.44 / 0.45 0.32 / 0.30 0.19 / 0.21 Pyrope 0.89 0.49 0.27 0.21 ∇2ρ(rc) Exp_Amb 8.5 3.3 5.1 2.7 Exp_1GPa 9.2 1.0 4.4 2.8 TR1 6.0 / 17.2 5.0 / 8.0 4.2 / 5.1 3.3 / 3.4 TR2 6.0 / 17.4 5.0 / 8.2 4.2 / 5.1 3.4 / 3.5 TR3 6.0 / 17.6 5.0 / 8.3 4.2 / 5.2 3.4 / 3.6 TR4 6.0 / 17.7 5.1 / 8.4 4.3 / 5.2 3.5 / 3.6 TR5 6.8 / 19.0 6.0 / 9.3 4.7 / 5.6 4.1 / 4.2 Pyrope 17.0 8.3 3.1 1.8 Destro et al. (2017) (Mg instead of Ca). †Two non-equivalent Ca—O contacts exist in this structure.

First of all, it is worth considering whether or not properties at BCPs for data obtained experimentally are comparable with those obtained theoretically and vice versa. Of course, one has to remember that each refinement is characterized by a slightly different value of the unit-cell parameter, which can affect the properties considered. The value of the a parameter in the case of TR1 and TR2 is equal to the value obtained experimentally for synchrotron and laboratory measurements, respectively. For theoretical refinements 3, 4 and 5, the a parameters were freely refined and achieved the values 11.82951 (10), 11.80797 (10) and 11.63202 (10) Å, respectively.

When comparing the distances from particular ions to the corresponding BCPs (d_1-bcp and d_2-bcp in Table S4), one can see that theoretical values at ambient pressure and at 1 GPa are quite consistent. The values hardly shrink in accordance with the shrinking of the unit-cell parameter and mimic the experimental values quite well. However, the results from XD2016 are not identical to those from TOPOND. There seems to be a small systematic positive difference between the d_1-bcp values obtained with XD2016 and TOPOND. Of course for d_2-bcp the relation is the opposite. The best agreement between the experimental and theoretical parameters is observed for the values of the electron density at BCPs (ρ(r_c) in Table 4). In the case of Al—O, all the theoretical values are consistent when compared with the experimental ones, but underestimated by about 0.1 e Å⁻³. However, Al—O is not the best example to judge agreement of theoretical calculations with experimental results. This is because Al is partly substituted by Fe (discussed in the Introduction).

On the other hand, for Ca—O^I, both XD and TOPOND slightly overestimate the values of the density, whereas for Ca—O^II, both types of calculations correspond with experimental results quite well.

More significant are the differences between theoretical and experimental values of the Laplacian (∇²ρ(r_c) in Table 4), which, as the second derivative of the charge density, is very sensitive to a change. In fact, results are consistent only in the case of the Ca—O^I interaction. For Ca—O^II, both types of theoretical calculations give slightly higher values of the Laplacian than the experimental ones. For Si—O, when considering the discrepancies between the results obtained from XD and TOPOND, no clear conclusion can be drawn concerning the comparison with the experimental results. It is interesting however to notice that theoretical values of the Laplacian obtained from TOPOND are almost identical to the literature data for isostructural pyrope (Destro et al., 2017) and closer to the experimental values determined in this work. In the case of Al—O, both theoretical calculations are discrepant from each other, but both give higher values for the Laplacian than those obtained from the experiments. To conclude this part, it seems that calculations are generally in good agreement with the experiments, at least in the case of charge density at BCPs, but the results for the Laplacian are much less consistent.

The next step is to compare results of our experiments with literature data. Because experimental and theoretical electron densities have been already determined for quite a few minerals, there are literature references of interest showing values of charge density and its Laplacian at BCPs. For example, the charge density topology of pyroxenes described by many authors between 1969 and 2001 was discussed by Downs (2003) and can work in this comparison.

However, the most relevant example of EDD described in the literature concerns pyrope (Destro et al., 2017), which is isostructural with grossular (pyrope in Table 4). However, data for pyrope were collected at 30 K and the multipole model was developed up to the tricontadipoles (hexadecapoles in this work) and the calcium atom was substituted by a magnesium atom. Moreover, Destro and co-workers also used ADPs augmented by Gram–Charlier expansion with coefficients up to the third order for Si and O, and up to the fourth order for Mg and Al, whereas we used only the second-order ADPs for each atom type. Still, there is excellent agreement between the above datasets. In the case of Ca—O/Mg—O contacts, it is difficult to compare them as they involve completely different elements. Surprisingly, the values of electron density, Laplacian or energy densities seem to be quite similar. This may result from the fact that both atoms contribute two valence electrons and are quite alike in terms of chemical properties.

Aside from the case of pyrope, we can also look into some other examples. In the case of properties at the BCP for the Si—O bond, the literature is quite rich because many silicates have been investigated so far. As the values of charge density ρ and their Laplacian ∇²ρ depend on bond length, studies which take this into account are very informative (Gibbs et al., 2005, 2014). Considering that, at ambient pressure, the Si—O bond distance in grossular is 1.6466 (2) Å (in-house experiment), on the basis of the mentioned literature, the values of the charge density ρ and the Laplacian ∇²ρ are expected to be around 0.88 e Å⁻³ and 18.5 e Å⁻⁵, respectively. The results obtained in our study are different, especially for the Laplacian. The values of ρ and ∇²ρ are equal to 1.15 e Å⁻³ and 8.5 e Å⁻⁵, respectively (see Table 4). The value of the Laplacian is therefore ca 50% smaller than expected.

For Al—O and Ca—O bonds, there is literature describing the electron density distribution in minerals such as topaz, Al₂(SiO₄)F₂ (Ivanov et al., 1998); α-spodumene, LiAl(SiO₃)₂ (Kuntzinger & Ghermani, 1999; Prencipe et al., 2003); natrolite, Na₂(Al₂Si₃O₁₀)·2H₂O; mesolite, Na₂Ca₂(Al₂Si₃O₁₀)₃·8H₂O; scolecite, Ca(Al₂Si₃O₁₀)·3H₂O (Kirfel & Gibbs, 2000); danburite, CaB₂Si₂O₈ (Luaña et al., 2003); diopside, CaMgSi₂O₆ (Bianchi et al., 2005a); datolite, Ca[BOH(SiO₄)] (Ivanov & Belokoneva, 2007); and clinopyroxene, LiGaSi₂O₆ (Bianchi et al., 2005b).

When we look at values of ρ and ∇²ρ at BCPs for the Al—O contacts in the above mentioned minerals, it is clear that the closest crystal environment has a significant influence on these parameters, and discrepancies are noticeable. The average values of ρ and ∇²ρ are equal to 0.658 e Å⁻³ and 14.81 e Å⁻⁵ (natrolite), 0.71 e Å⁻³ and 10.76 e Å⁻⁵ (mesolite), 0.67 e Å⁻³ and 12.31 e Å⁻⁵ (scolecite), or 0.64 e Å⁻³ and 4.78 e Å⁻⁵ (topaz). In our studies of grossular, we observe ρ = 0.515 e Å⁻³ and ∇²ρ = 1.394 e Å⁻⁵ (see Table 4).

When we take into consideration the properties at BCPs of Ca—O, discrepancies are also significant. Experimental values of ρ vary between 0.142 (3) e Å⁻³ and 0.184 (5) e Å⁻³ (danburite), 0.11 (1) e Å⁻³ and 0.26 (1) e Å⁻³ (diopside), and 0.114 e Å⁻³ and 0.360 e Å⁻³ (datolite). In mesolite and scolecite, the average value of ρ is equal to 0.226 e Å⁻³. As a result, the values of the Laplacian also vary from 3.23 e Å⁻⁵ to 4.14 e Å⁻⁵ (danburite), 1.9 (1) e Å⁻⁵ to 4.8 (1) e Å⁻⁵ (diopside), and 1.81 e Å⁻⁵ to 5.47 e Å⁻⁵ (datolite). In mesolite and scolecite, the average value of the Laplacian is equal to 3.57 e Å⁻⁵. For grossular (in this study), at two BCPs describing the Ca—O contacts, the values of ρ and ∇²ρ are as follows: 0.192 e Å⁻³ and 2.979 e Å⁻⁵, and 0.275 e Å⁻³ and 4.785 e Å⁻⁵, which are in very good agreement with the literature data.

Another issue to consider is the potential differences in the integrated properties of the electron density obtained by performing atomic basin integration. Details about atomic volumes and net atomic charge obtained from atomic basin integration conducted in TOPXD (both on experimental and theoretical data) are presented in Table 5.

Table 5 Integrated volume of atomic basin V (Å3) and net charge Q (e) for the four atomic species of grossular   Ca Si Al O   V Q V Q V Q V Q Exp_Amb 11.28 1.96 5.63 2.24 4.78 1.95 12.32 −1.38 Exp_1GPa 11.22 1.66 4.49 2.79 3.87 2.21 12.87 −1.47 TR1 11.13 1.65 3.41 3.05 3.25 2.67 13.28 −1.60 TR2 11.09 1.65 3.39 3.05 3.23 2.67 13.21 −1.60 TR3 11.01 1.65 3.32 3.07 3.20 2.67 13.12 −1.60 TR4 10.95 1.64 3.30 3.07 3.18 2.67 13.05 −1.60 TR5 10.50 1.63 3.18 3.08 3.09 2.67 12.45 −1.60 Pyrope† 6.98 1.62 5.74 2.82 4.16 2.69 11.72 −1.55 †Destro et al. (2017).

When one takes into consideration the net atomic charge for ions (both experimental and theoretical results), we see some differences. Comparison of Exp_1GPa and TR1 (same a parameter) shows the most significant differences in the case of the Al cation (0.46 e); for other ions the difference is much smaller. Comparison of Exp_Amb and TR2 (the same a parameter) also shows a significant difference (0.72 e) in the case of the Al cation, but in the case of the Si cation it is even larger (0.81 e). However, one must remember that, in this natural piece of grossular, Al is partly substituted by Fe (0.26 to 1.82%) which is why all figures devoted to Al could be slightly biased.

It must be stressed that although theoretical calculations correspond very well with Exp_1GPa, Exp_Amb deviates from Exp_1GPa as well as from theoretical calculations. The sum of charges per molecule defined as Ca₃Al₂Si₃O₁₂ is equal to −0.06 e and +0.13 e for the ambient conditions and 1 GPa, respectively. For the corresponding theoretical calculations, this sum of charges is equal to +0.24 e for TR1 and TR2.

The largest values of Lagrangians were observed for silicon ions: 3.08 × 10⁻³ Ha and 2.56 × 10⁻³ Ha under ambient conditions and 1 GPa, respectively. One should remember that, for molecular crystals such as oxalic acid, sample standard deviations (SSD) for integrated atomic volumes and atomic charges range from 0.1 to 0.3 ų and from 0.02 to 0.10 e Å⁻³, respectively, so the discrepancies from neutrality, as well as the observed effects of pressure for the integrated properties are within +/−1 SSD (Kamiński et al., 2014).

For the atomic volumes, the most significant differences between experiment and theory are those observed for the Si atomic basin. The difference between Exp_1GPa and TR1 is 1.08 ų (32% towards the theoretical value), and between Exp_Amb and TR2 is 2.24 ų (66% towards the theoretical value). The smallest differences are observed for the atomic basin of the Ca cation and oxygen anion. Again, Exp_Amb deviates from Exp_1GPa as well as from theoretical calculations

Integrated atomic volumes for Si and Al in Exp_Amb are larger than expected. On the other hand, they are very consistent with the results of experimental density analysis for pyrope (Destro et al., 2017), possibly illustrating an effect inherent to experimental data.

In the case of calcium/magnesium cations, the literature values are noticeably smaller. However, this is not surprising since the Mg cation is expected to show a smaller volume than the Ca cation.

Another way to identify certain differences between results obtained for Exp_Amb and Exp_1GPa is to compare contour maps for properties such as the total electron density, deformation electron density or Laplacian of the electron density. Such maps are presented in Fig. 3 for the Ca–Si–O plane.

Figure 3 Maps of electron density distribution for the Ca–Si–O plane. Contour values for total density and deformation density are 0.1 e Å−3 and 0.05 e Å−3, respectively. For Laplacian maps, particular contours are ±2, 4, 8, 20, 40, 80, 200, 400 and 1000 e Å−5. Blue contours denote positive values and red contours correspond to negative values. The same color scheme is adopted for the deformation density maps.

In the total density plots (upper rows of Fig. 3), one can clearly see the aspherical shape of the valence electron density for all ions. However, the effect of the applied pressure is hardly seen even on the Laplacian maps. The most significant difference possible that can be observed is between the deformation density map for TR1 and for both experiments. In the case of theoretical calculations, the electron density around oxygen ions is shaped differently (more smooth) than in the case of the experimental results.

All these different shapes of electron density on maps in Fig. 3 result from sections of 3D maps of electron density through particular planes defined by the Ca–O–Si plane. Corresponding 3D deformation electron density maps are displayed in Fig. 4 for SiO₄ (first row) and CaO₈ (second row), illustrating changes at the ±0.1 e Å⁻³ isosurfaces of the electron density.

Figure 4 3D deformation electron density maps; (first row) SiO4, (second row) CaO8. From left to right: experimental ambient pressure Exp_Amb, theoretical calculations TR2, experimental high-pressure Exp_1GPa and corresponding theoretical calculations TR1. Blue contour: +0.1 e Å−3; red contour: −0.1 e Å−3.

As illustrated in Fig. 4, the theoretically calculated 3D shapes of deformation density are more similar to those obtained on the basis of experimental data in the case of SiO₄ than in the case of CaO₈. Si—O contacts have more covalent character than Ca—O contacts, which are more ionic. However, the resemblance between particular 3D deformation maps can be attributed to the type of data (theoretical results are similar to theoretical ones and experimental results are similar to the experimental ones) rather than the pressure value (or value of the a parameter).

All the above mentioned similarities between the electron density distribution at 1 GPa (synchrotron measurements) and at ambient pressure (laboratory measurements) as well as their consistency with the literature data describing isostructural compounds suggest two facts. Firstly, during the measurement at 1 GPa, enclosing the sample in a DAC did not prevent the acquisition of a dataset of quality good enough to refine a reasonable Hansen–Coppens multipole model of electron density. Secondly, the pressure difference between the two experiments considered was too small to observe significant differences in properties at the BCPs.

4.1. Data availability

Data supporting the findings of this study are available from the correspondence author upon reasonable request. CCDC 1936438–1936441 entries contain the supplementary crystallographic data for grossular at ambient conditions and under pressure. These data can be obtained free of charge from the Cambridge Crystallographic Data Centre via https://www.ccdc.cam.ac.uk/data_request/cif.