2.1. Definitions and methodology

Volume G of International Tables of Crystallography (Hall et al., 2006) defines completeness as a fraction of unique reflections measured to a given resolution, usually 0.6 Å⁻¹ in non-macromolecular structures. While informative and concise, this definition leaves room for interpretation, as it does not strictly define a complete dataset. For example, a systemically extinct reflection is not considered missing, as its presence is unexpected in the first place.

Following this example, we can adapt the classical definition of completeness so that it disregards any reflections that are unobtainable using specific equipment, such as a DAC, similarly to how the classical definition disregards signals which are systematically extinct. This `applicable completeness', , is a ratio between numbers of obtained and obtainable unique reflections in a given space group and up to a certain resolution. According to this definition, is a quality descriptor of experimental strategy and as such can always assume values between 0 and 1, independent of the equipment used. All experimental strategies can and should be planned, so that the applicable completeness of collected data is as close to 100% as possible.

The ratio between `classical' completeness and `applicable' completeness for any experiment compares the number of reflections obtainable using a given setup to the total count of signals available theoretically. As such, it is independent of individual measurement and describes the potency of experimental setup instead. This potency, , is the maximum classical completeness of data collectable using a specified experimental setup.

For the majority of standard diffraction techniques, the availability of a modern goniometer and good incident sources rarely disallow the potency to reach 100%. Notable exceptions include diffraction techniques which utilize HP anvil cells or electron beam sources. In both cases, individual crystals can be rotated only partially during the experiment, preventing one from measuring diffraction from planes perpendicular to the incident beam.

2.2. Restrictions in HP experiments

The subject of HP experiment potency was presented in a classical paper by Merrill & Bassett (1974). Therein, the authors present a formula for volume of reciprocal space accessible to their DAC for a monochromatic incident beam. Assuming a DAC opening angle of α and radiation wavelength of λ, it can be expressed as

In typical experiments the diffraction is measured only up to a certain angle Θ, related to expected resolution d_min in accordance with Bragg's Law. The region in which one collects data can be thus limited not only by the DAC, but also by a virtual sphere S_Θ of radius 2sinΘ/λ, bringing the accessible volume to

The percentage of reciprocal space accessible up to a given resolution threshold can be calculated analytically. It is the ratio between the HP-accessible volume V_c and the volume of space contained within the sphere S_Θ, denoted V_Θ:

Typical values of the V_c to V_Θ ratio, presented in Table 1, approximate well the potency of the relevant HP experiment assuming all reflections are symmetry-independent. In reality, internal symmetry and sample orientation heavily influence the potency of the experiment, as information contained in unavailable reflections will be carried by their symmetry equivalents. Since the orientation of a single crystal relative to a DAC can not be changed during an XRD experiment, it will be considered a part of the experimental `setup' (and not part of the measurement strategy) in further discussion.

The term `opening angle' of a DAC is used somewhat inconsistently in the literature. Some authors define opening angle α as the angle between the vector normal to the diamond surface and a limiting vector which glides along the metal body of a DAC (Fig. 1), whereas others use it to describe the maximum value of 2θ obtainable in a diffraction experiment. In this work we use the term `opening angle' to express the former, while terms `double opening angle' or occasional `aperture' relate to the latter.

Figure 1 Total reciprocal space available to the pressure cell with the opening angle α, limited by investigated resolution sphere SΘ down to VC. Assuming all reflections are symmetry-independent, the hypothetical experiment measured 6 out of 8 measurable and 20 total reflections, resulting in and of 75 and 30%, respectively. of this setup, assuming `orange' orientation of the sample, is 40%.

2.3. Methods for estimating potency

In simple cases, the potency of the experimental setup can be estimated analytically via direct integration over reciprocal space, as presented above. Unfortunately, derived formulas become exponentially more complicated with each symmetry element present; they are also not exact, as they describe the percentage of available reciprocal space volume instead of counting actual, symmetry-independent reflections.

In order to calculate the impact of experimental conditions on potency, we instead opted for a direct numerical approach. For that reason a custom-made Python3 library nicknamed Hikari was utilized. The package has no dependency on other professional tools and instead operates using basic crystallographic formulae and generic functions from common libraries, making it very expandable, but relatively slow. The workflow used to estimate potency is presented in Fig. 2.

Figure 2 Procedure for potency evaluation using Hikari. In this example reciprocal space has mm point-group symmetry, there are 17 non-extinct symmetry-independent reflections (purple), 12 of which can be found within the DAC-accessible region (orange). Thus the potency of this experimental setup is ∼70.5%.

After interpreting input crystallographic data, Hikari generates reciprocal space nodes contained within a limiting sphere of desired radius. Extinct reflections are removed if necessary, after which all nodes are evaluated in terms of symmetry and independent nodes are counted. Then, for each investigated DAC orientation, an available region is determined, independent nodes within are counted and potency is evaluated.

The following procedure can be applied in many scenarios. Initial nodes can be generated based on an experimental diffraction file or only for a selected subspace (i.e. hk0 plane). Resolution limits, wavelength and opening angle can be varied; any list of sample orientations can be used. Finally, various unit cells and symmetry settings can be investigated.

The program can be used to evaluate existing experiment and experimental setup by counting symmetry-independent nodes excluded by a DAC (Table 2). Iterative application of this procedure for a series of orientations can be used to estimate optimal sample placement or investigate influence of DAC geometry (Figs. 3–7 and Section S5.1 of the supporting information). Feeding the algorithm with the correct structure factors allows one to estimate an impact of DAC restrictions on refinements against data collected previously (this functionality will be discussed elsewhere). In its current form, Hikari is available at https://github.com/Baharis/hikari. A dedicated server with interactive potency maps is under development.

Table 2 Classical completeness, applicable completeness and potency of the data collected to 0.6 Å−1 in the HP experiments performed Series Phase, pressure (kbar) Third α, 2 92.91% 99.49% 93.39% First α, 5 91.91% 98.51% 93.30% Second α, 8 91.12% 99.64% 91.45% Third γ, 10 93.81% 100.00%† 93.81% First γ, 12 92.14% 98.68% 93.37% Third γ, 13 93.64% 100.19%† 93.46% First δ, 20 92.91% 99.66% 93.22% †Artificially inflated by weak signals of δ erroneously included by software.

Figure 3 Reciprocal space coverage as a function of opening angle α presented for a series of Θ limits according to Equation (4). The Θ lines which translate into the most common combinations of radiation wavelengths and resolution limits have been highlighted. Assumed Laue class: −1.

2.4. Effect of opening angle

The majority of single-crystal HP experiments are performed using the cell of Merrill-Bassett or a similar design (involving two opposite diamond anvils). Although individual implementations can vary, basic expressions for accessible volume, presented in Equation (4), tend to be fairly applicable. Thus, the DACs can be usually described using only their opening angle.

Apertures 2α of commercially available cells tends to vary between 60 and 80° (α = 30 or 40° accordingly). Quite recently, DACs with a nominal double opening angle of 120° (α = 60°) have also become available. In our experience the actual opening angle tends to be reduced due to gasket thickness or sample–gasket proximity (schematically explained in section S5.3 of the supporting information). For that reason, opening angles (α) of 35 or 55° will be discussed in more detail.

Reciprocal space coverage as a function of the opening angle of a DAC is graphically presented in Fig. 3. In the considered range of opening angles and resolution limits the coverage is almost proportional to Θ and the slopes of lines representing selected Θ values are very similar. The impact of the opening angle α is quite apparent. For the combination of Mo Kα radiation and the IUCr diffraction limit of 0.6 Å⁻¹, increasing the opening angle from 35 to 55° roughly doubles the reciprocal space coverage from 27 to 59%. The same effect is even more apparent in Fig. 4.

Figure 4 Violin plots representing the distribution of experiment potency for 50 000 uniformly distributed crystal orientations each, presented for commonly used laboratory wavelengths and DAC opening angles. The resolution limit for all plots assumed at sinΘ/λ = 0.6 Å−1. Dashed lines represent quartiles of each distribution. Further descriptive statistics are available in Table S5.1. Opening angle and sample orientation in conjunction with sample symmetry strongly influence potency even in the cubic system, where placing the crystal on one of the {100} planes can result in an incomplete dataset.

2.5. Effect of crystal orientation

The internal symmetry and the placement of a crystal in the DAC play a secondary role when it comes to experimental potency, but their influence should not be underestimated. A DAC with a large aperture will always have an advantage over its counterparts, but attentive consideration of symmetry can increase the amount of collected data up to fourfold if performed correctly.

The disk-like shape of DAC-accessible volume features point group symmetry, which includes common symmetry elements of other point groups. In particular, the point group contains a center of inversion, which coincides with the appropriate center in crystal point groups at (000). Thus, lattice points (hkl) and (hkl) are always both available or both unavailable. Since the availability of space is centrosymmetric, the potency for each point group can be estimated using its Laue class, limiting the number of cases from 32 to 11.

The symmetry offered by point group −1 can not be used to increase the completeness of obtained data. Both symmetry elements present here coincide with the internal symmetry of the disk; as a result equivalent reflection pairs are always either both available or both unavailable, as discussed above. As such, in the case of Laue class −1 the potency is virtually independent of sample orientation and constitutes a baseline for other groups (Fig. 4). Nonetheless one can still attempt to use multiple differently oriented crystals to increase the final completeness (Casati et al., 2016, 2017; Tchoń & Makal, 2019).

More possibilities are offered by the monoclinic crystal system, whose only Laue class 2/m is a subgroup of when the twofold axis coincides with either or an -perpendicular plane. In other cases it is possible for information outside the DAC-accessible disk to be included via registered, symmetry-equivalent reflection, effectively increasing the completeness of collected data above the value from Equation (4). Depending on the orientation, the potency of the HP experiment in the case of a monoclinic sample investigated using Mo Kα radiation in a DAC with α = 35° up to sinθ/λ = 0.6 Å⁻¹ can be as low as 27% or as high as 50% (Fig. 4, top left).

In a similar fashion the potency for samples whose diffraction patterns belong to the Laue class mmm, 3, 3m, 4/m, 4/mmm, 6/m or 6/mmm can fall to the −1 baseline, as all those classes are sub-groups of whenever is parallel to their main axis. Ensuring that the main crystal axis does not coincide with the diamond culet normal has a great impact on final completeness, especially where α is small. In such case maximal achievable potency reaches 70% for trigonal 3, ∼75% for orthorhombic mmm or tetragonal 4/m, and over 85% for the remaining Laue classes (Mo Kα up to sinθ/λ = 0.6 Å⁻¹). Finally, while Laue classes m3 and m3m are not subgroups of in any orientation, they still benefit from distancing their symmetry elements from axes and planes of and experiment potency can be as low as 70% or as high as 100% (Fig. 4, top left).

It has been shown that various groups of reflections differ in their significance during crystal structure determination (Merli et al., 2002). According to Parsons et al. (2012), weak high-resolution data can be very important in distinguishing between centrosymmetric and noncentrosymmetric models, as the leverage of weaker reflections seem to be higher during determination of their structure. Therein the leverage also did tend to increase with resolution. As shown in Fig. 5, toppling the main crystal axis with respect to the culet normal (z for tetragonal here) increases the relative completeness up to fourfold for the highest resolution shell and about twofold for the lowest resolution shell.

Figure 5 Average shell completeness for a model tetragonal crystal (left) and 2°AP-α (right) as a function of data resolution, assuming Mo Kα wavelength and 35° opening angle. Different lines indicate topple angles between the (001) direction and the diamond culet normal. The relative increase in completeness is observed mainly at higher resolution, where data have high importance for correct space group determination. In the tetragonal case, tilting the crystal increases completeness fourfold in the highest resolution shell and `only' about twofold in the lowest resolution shell.

2.6. Orientation potency maps

Since crystal placement has a significant impact on obtainable completeness, it would be of high interest to systematically present its influence on potency. The sample orientation, represented using a 3 × 3 UB matrix (Busing & Levy, 1967) defines the relation between the laboratory and sample reference systems as

where r is expressed in the laboratory reference frame, while h contains Miller indices of the point in reciprocal space (Paciorek et al., 1999).

In the laboratory reference frame, vector corresponds to the direction parallel to the incident beam which, in turn, coincides with the vector being normal to the diamond surface in a properly mounted anvil cell. As such, Miller indices h and Cartesian coordinates , describing the crystal face aligned with the diamond culet, can be obtained using Equations (6) and (7), respectively:

where represents a transformation matrix between said reference frames. Just as vector correlates to the rotational axis of the DAC in direct space, is aligned with the axis of the relevant DAC-accesible disk in reciprocal space. Note that, in the Ewald construction, vectors , and h all have a common direction, but are expressed in different coordinate systems.

Due to the symmetry of the DAC-accessible region, its orientation in reciprocal space is unambiguously described using said vector (or h). Accordingly, instead of investigating potency as a function of orientation, , it is sufficient to monitor the value of for each normalized vector . This reduces the problem at hand to a simple mapping, which can be represented in a comprehensible format.

Since corresponds to a direction in three-dimensional space, it is natural to represent its functions on an unit sphere, akin to Kikuchi lines. Depending on the Laue class, usually only a fraction of this sphere is necessary. Potency as a function of can be then represented using a color gradient, resulting in a figure analogous to a relief map of the Earth. Examples of such a potency map, generated for idealized samples, have been presented in Fig. 6 and more extensively in Section S5.1 of the supporting information.

Figure 6 Potency heat maps for selected Laue classes, assuming the most common combination of α = 35° and resolution limit of sinΘ/λ = 0.6 Å−1. Unit-cell parameters for tetragonal: a = b = 15 Å, c = 20 Å; for other crystal systems: a = b = c = 20 Å. Potency as a function of sample orientation is mapped onto an octant of a unit sphere. Each point corresponds to normalized indices of a reciprocal space vector perpendicular to the DAC culet surface. Red, green and blue vectors represent x*, y* and z*, respectively. Examples of culet-perpendicular planes and resulting potency have been labeled and marked on the map using hollow points.

Reading the potency map requires a basic understanding of relation between Miller indices h and reciprocal space coordinates in the investigated crystal. For example, basis vectors , and intersect a unit sphere at points [1,0,0], [0,1,0] and [0,0,1]. Accordingly, the color of the sphere at their position describes the potency for the crystal placed on faces belonging to the family {1,0,0}, {0,1,0} or {0,0,1}, respectively. However, the normalized vector does not describe completeness for a crystal placed on the (111) face, but rather for the orientation featuring perpendicular to the diamond culet. In order to check the completeness for the crystal placed on the (hkl) face, one needs to revert from Miller indices h to Cartesian coordinates . Since Fig. 6 (bottom left) describes a tetragonal crystal with a = b = 15 Å, c = 20 Å, the potency of a crystal placed on the (111) face is visualized at the normalized vector , or approximately [0.62, 0.62, 0.47], slightly below the center of the map.

The potency maps illustrate the impact of crystal symmetry on obtainable data completeness to the fullest extent and allow symmetry effects to be systematized and to expose certain paradoxes. Although most imaginable orientations in the case of m3 symmetry in the cubic system promise data completeness of nearly 100%, there are still a few which can seriously compromise it. Most importantly, there is not a single best direction that would ensure satisfactory reciprocal space coverage for all crystal systems. Placing a crystal on the faces perpendicular to crystallographic directions should generally be avoided. However, placing an orthorhombic crystal on its own, well formed (111) face in a typical DAC (35° opening angle) warrants very high completeness up to ∼75% whereas the same maneuver reduces it for a cubic sample from an achievable 100% to ∼70% (Figs. 4 and 6). In essence, a well oriented orthorhombic crystal can yield data more complete than a very poorly oriented cubic one.

3.1. X-ray diffraction experiment

2°AP was synthesized using the same synthesis protocol that has been formerly applied in obtaining 1-acetylpyrene and 1,8-diacetylpyrene. (Tchoń et al., 2019, 2021). Recrystallization from a mixture of dichloromethane and n-pentane yielded mainly good-quality block crystals of known polymorph α, with traces of new monoclinic phase β, which will be discussed elsewhere.

XRD data were collected using the Rigaku Oxford Diffraction SuperNova four-circle diffractometer equipped with Eos CCD detector, molybdenum microsource (Mo Kα, λ = 0.71073 Å) and an LN2 cooling device utilized while collecting a reference dataset at 100 K. Data collection and reduction were performed in CrysAlisPRO (Rigaku, 2015). Shape-based and empirical absorption correction were applied through the same software, using SCALE3 ABSPack (Oxford Diffraction 2015). Averaging, merging and outlier rejection were performed with SORTAV (Blessing, 1995). Further details of the procedures can be found in Tables S1.3 and S1.4 of the supporting information.

The reference and the three lowest-pressure datasets were solved in the space group Pnma using SHELXT and refined using olex2.refine (version 1.5-alpha) coupled with NoSpherA2, using the TAAM approach, with aspherical scattering factors provided by DISCaMB (Sheldrick, 2015b; Bourhis et al., 2015; Kleemiss et al., 2021; Chodkiewicz et al., 2018). The four higher-pressure datasets were solved and further refined assuming spherical scattering factors using SHELXT, SHELXD and SHELXL (Sheldrick, 2015a,b, 2010). Both procedures were performed within the Olex2 GUI (Dolomanov et al., 2009). Non-standard space group settings for new-found polymorphs, Pn2₁a for 2°AP-γ and P112₁/a for 2°AP-δ, were chosen for consistency (see Table 3).

The exceptionally high completeness of the obtained data allowed all atoms to be easily found and refined without the need for restraints. The hydrogen atoms were constrained to their closest carbons and had their movement defined using the riding approximation in an independent atom model, but were refined freely in four Pnma datasets, including anisotropic displacement parameters at 5 kbar.

Refinement with an aspherical atom model could not be used for the highest-pressure 2°AP-δ phase as the algorithms could not properly handle the HKLF5 twinned data format. In the case of 2°AP-γ, the TAAM approach with unrestrained C—H distances did not improve refinement statistics and led to shortening of some C—H bond lengths. This was possibly the result of the coexistence of the traces of δ phase alongside the γ phase, contaminating the intensities of low-resolution reflections.

Molecular graphics were prepared using either Olex2 (Dolomanov et al., 2009) or Mercury software (version 4.3; Macrae et al., 2008). The data were deposited with the Cambridge Structural Databaseand assigned CCDC deposition numbers 2096512–2096519.

3.2. Sample placement and data completeness

The collection of reference data for 2°AP-α at 100 K required mounting a monocrystal on a Mitegen loop using a trace amount of paraton oil and running a series of ϕ-scans to collect all data up to sinθ/λ = 0.9 Å⁻¹. The data collection strategy for the seven HP experiments, performed in three independent series, utilized the crystal mounting strategy proposed in this paper.

The orientation potency map prepared for 2°AP-α showed that the Mo Kα wavelength and 55° opening angle could offer final completeness between 59 and 99%. Unfortunately, the lowest potency corresponded to placing the crystal on one of the {100} faces, both of which were among the largest in the specimen obtained. Meanwhile, the most potent geometry required the alignment of the diamond normal to 〈111〉 (or using Miller indices ), which did not correspond to any of the faces observed. Since the desired orientation could not be achieved naturally, in order to maximize potency of the prepared anvil cell, the specimen faces were indexed using preliminary XRD screening, after which they were mounted on the diamond culet with a trace amount of epoxy glue in an orientation as close as possible to that desired. The 2°AP-α potency map with final orientations marked is presented in Fig. 7.

Figure 7 Potency heat maps prepared for 2°AP-α, 2°AP-γ and 2°AP-δ in the initial Laue class mmm (top), and in the final 2/m (bottom), assuming an opening angle of 55° and a 0.6 Å−1 resolution. The sample orientations in the HP experiments performed are marked; marked colors represent crystal phases and marked shapes correspond to individual packing series. As expected, the orientation is preserved in individual series, the only exception being δ, whose two domains appear during phase transition-induced twinning.

After mounting the sample, a DACOne20 cell with an effective opening angle of 55° was equipped with a 300 µm steel gasket with a 300 µm hole, and filled with Paratone-N as a pressure-transferring medium. The pressure was estimated by the ruby fluorescence method using dedicated software. In total, seven collected datasets probed the pressure range up to 2 GPa. Their completeness was found to be very satisfactory as shown in Table 2.

3.3. Crystal packing

2°AP-α and its HP relatives, γ and δ, exist as three variants of a common packing scheme. They arrange a_z glide plane-related 2°AP molecules in offset β-type stacks (Desiraju & Gavezzotti, 1989) along X, forming jagged columns, a motif described previously by Rajagopal et al. (2014) as lamellar. These columns interlock with one another, creating a brick-layer motif analogous to those found in 1,8-diacetylpyrene.

Just as π-stacking stabilizes the brickwork along x and z, polar interactions bind them along y (see Table S3.2). Each of the participating molecules donates a pyrene hydrogen and carbonyl oxygen atoms on both sides, allowing for two hydrogen bonds on each edge; thus infinite chains of intertwined 2°AP and R₂²(14) motifs (Etter, 1990) are formed in the process, as shown in Fig. 8.

Figure 8 Crystal packing featured in the 2°AP-α family observed from y and x. Left: offset stacks of 2°AP molecules interlocked, creating brick-layer motifs in the xz plane. Right: neighboring brick-layers interact in the y direction via double hydrogen bonds on each side of each layer.

Compression of 2°AP-α leads to a loss of symmetry, e.g. an increase of Z′ from 0.5 to 1 and the disappearance of the m_y mirror plane. An additional degree of freedom granted to the a_z-related molecules allows them to tilt around z which, in turn, causes the whole brickwork to lean in one direction. The tilt of closest layers might either alternate in a herringbone-like fashion or coincide. The first case preserves the 2₁ axis in the y direction, resulting in a wavy-variant of α, orthorhombic 2°AP-γ. The second case preserves 2₁ along z, but in turn topples the entire lattice to one side, producing monoclinic 2°AP-δ (Fig. 9). Due to equal probability of layers toppling `right' and `left', the crystal samples of δ tend to be twinned. Despite discarding half of symmetry elements, both γ and δ perfectly preserve the overall interaction network of 2°AP-α, as presented in Section S3 of the supporting information.

Figure 9 Schematic representation of crystal packing variations observed in 2°AP polymorphs as seen from z. Applied pressure gradually tilts individual stacks, leading to either orthorhombic γ or monoclinic δ.

3.4. Phase transition

New polymorphs of 2°AP discussed in this work are both obtained by the means of gradual pressurization of the commonly known crystal form α. On applying approximately 1 GPa of pressure, α undergoes a subtle phase transition towards orthorhombic 2°AP-γ. Both polymorphs feature virtually equal lattice constants and very similar packing schemes. The RMSD between molecular structures of α and γ investigated under similar pressure conditions is at the level of 0.02 Å.

The crystal forms are even harder to distinguish in reciprocal space. 2°AP-α and 2°AP-γ share not only the same primitive orthorhombic unit cell, but also all extinction rules. Furthermore, structure factor statistics of 2°AP-γ show values characteristic for centrosymmetric systems despite Pn2₁a being a non-centrosymmetric space group. This may stem from the fact that the tilt oft the 2°AP molecule resulting in the loss of the m_y mirror plane can occur in either direction, resulting in racemic twinning, as well as from the coexistence of the traces of δ alongside the γ phase, contaminating the intensities of low-resolution reflections, see Fig. 10(b). Finally, the prevalence of both space groups in the CSD is also rather similar. As such, differentiation between 2°AP-α and 2°AP-γ in reciprocal space was found to be extremely difficult. Instead, the correct space group was assigned based on agreement factors and the absence/presence of tilt in direct space (a detailed description is given in Section S1.6 of the supporting information). Although the difference between α and γ is very small, here it could be identified due to well defined atomic displacement parameters, resulting from high completeness of HP datasets collected.

Figure 10 (a)–(c) Reconstructed diffraction patterns in (hk0) and (0kl) of α at 8 kbar, γ at 13 kbar and δ at 20 kbar, with diamond signals marked in cyan. Transition to a monoclinic system is gradual and already visible in the pattern of γ. (d) The δ (0kl) plane features partial extinctions characteristic for the nx glide plane; violations of such extinctions are only discernible at high resolution (inset, k = 12 and k = 14).

The transition to the δ phase is, in turn, easy to observe due to the abrupt change of crystal system; however it is riddled with other problems. Firstly, the crystal samples of δ are systematically twinned around the 2_y axis (2_1y being lost in the transformation), in accordance with the former studies of twinning under pressure (Friese & Grzechnik, 2014). More interestingly, the transition does not occur at a fixed pressure. Traces of the δ diffraction pattern appear concurrently with γ, and then gradually overshadow it, dominating the image completely around 2 GPa. Within this range the reciprocal lattice tends to be decorated with three distinguishable patterns: one of disappearing γ and two for twinned δ.

Due to strong structural similarities the diffraction pattern of δ features almost the same extinctions as α and γ. The extinction rule of the n_x glide plane, 0kl: k+l = 2n, is broken only for high-resolution reflections, as presented in Fig. 10(d). This observation was possible due to the careful design of this experiment, as orienting the crystal on its largest face (001) or (001) would leave the (0kl) plane highly incomplete.

As far as our tests go, all phase transitions presented here are reversible, though some loss in overall pattern quality can be observed.