2.1. Sample preparation

Initially, we prepared a liquid sample comprising C₆F₆ and C₄H₅N in a 1:1 molar ratio as for a columnar adduct. An X-ray glass capillary (Ø = 0.4 mm, length 85 mm) was initially shortened by around 10–15 mm so as to fit into a Microhematocrit centrifuge. The neck of the capillary was charged with a drop of the liquid mixture via pipette and centrifuged for about 30 s at 360g. Great care must be taken not to smash or damage the capillary in the centrifuge before subsequent removal of the capillary neck by flame sealing. As noted previously, it is important for the capillary to be 100% sealed as even a micrometre-sized perforation in the capillary wall can result in slow loss of volatile components over time (Bear et al., 2020). Further details of the materials used are given in the supporting information.

2.2. X-ray diffraction

After mounting on the SCXRD instrument, the capillary containing the C₆F₆:C₄H₅N was cooled rapidly in situ to 230 K resulting in the formation of numerous white crystals. The temperature was then raised until the crystals fully melted, before subsequent cooling back to 230 K. The temperature was then increased to 260 K, (just below the melting point at 266 K) in order to encourage annealing of single crystals present. The sample was held at 260 K for 2 h before cooling to 254 K for data acquisition. Initially, a full sphere of data was collected to ca 0.84 Å resolution using an Agilent Oxford Diffraction Supernova diffractometer upgraded with a Rigaku HyPix Arc-100 detector (Fig. S1 of the supporting information) in about 2.5 h. Subsequently, the sample was cooled to 150 K and a further full sphere of data was collected. Further details are given in the supporting information.

2.3. Differential scanning calorimetry

Differential scanning calorimetry (DSC) data were measured on a new sample of (C₆F₆)₃:(C₄H₅N)₄ prepared knowing the actual ratio of 3:4 for the components obtained from the SCXRD results. Further details are provided in the supporting information.

3.1. Traditional practice versus many crystals in the beam

Single-crystal diffraction is exactly that: the concept of rotating just one crystal in an X-ray beam while measuring diffracted intensities, a technique which dates back to the earliest days of X-ray crystallography by Bragg & Bragg (1913). Traditionally, a single crystal is carefully selected with the aid of an optical microscope (ideally equipped with cross-polarizing filters) before mounting it onto a goniometer head prior to measurement. This requires a high degree of skill on the part of the crystallographer. Indeed, with the current generation of laboratory-based instruments setup with automatic data collection and reduction, and structure solution and refinement, the selection of the crystal is perhaps one of the few skills left!

But what does the crystallographer do when the sample is not a solid under ambient conditions? There are many chemical systems of interest where the substance under investigation is a liquid at room temperature, but exhibits one or more crystalline phases on cooling. The traditional approach is to try to grow a single crystal at low temperature, using a cooling/heating device with a very precise temperature controller. Examples of devices include the use of a focused halogen lamp, filtered for all but red light (Goddard et al., 1997), or an infrared laser to melt a sample held in the capillary while holding the sample at a particular temperature (Thalladi et al., 1998; Choudhury et al., 2005). Although this approach has the advantage of potentially producing just one crystal in the X-ray beam, it has several drawbacks. The experimental setup with an infrared heating laser requires extra equipment inside the X-ray radiation enclosure, which involves additional expense and health and safety considerations. Secondly, the operation of a laser to grow a single crystal in situ requires a high degree of skill, with significant time expended on the part of the user. Alternatively, for some molecular systems, it may be possible if given enough time to grow a single-crystal in situ via repeated melting and cooling cycles (Yufit & Howard, 2010; Yufit et al., 2012).

The difficulty of growing just one single crystal from a liquid in the laboratory can potentially be overcome by forming several crystals in situ and then analysing the X-ray diffraction data using the multigrain approach first developed at synchrotron facilities with hard X-ray sources. We found that the combination of using CrysAlis PRO for identifying a crystal of significant size and finding the correct unit cell, followed by SHELXT to rapidly solve the structure from a limited resolution dataset is a powerful tool in this regard.

Our approach with a liquid mixture, illustrated with a flow diagram in Fig. 1, is to cool the sample into the solid state and screen the capillary with X-rays (stages I and II). There are several possibilities: the sample forms large macroscopic crystals from the outset, it forms a large number of smaller crystallites, it forms a crystalline powder or it forms an amorphous solid. In our experience, these co-crystal systems rarely form ideal crystalline powders even when the sample is quenched at low temperature. This implies that the structures cannot be determined reliably from powder X-ray diffraction (PXRD) data. We note that, in our previous work on C₆D₆:C₆F₆, the sample was ground in liquid N₂ so as to obtain an ideal powder and that simply taking a frozen sample of C₆D₆:C₆F₆ through three solid-state phase transitions does not achieve this, even with the large-volume samples typically used for powder neutron diffraction.

Figure 1 Flow diagram showing the overall process followed in our approach to obtaining single-crystal-quality data from a polycrystalline sample. The different stages of the process are illustrated on the right-hand side. Stage I illustrates the frozen capillary which is then screened with the X-ray beam (stage II) to test if large multiple crystals are present (as seen here) or whether the sample is simply a polycrystalline powder. If the unit-cell determination from the screening frames (stage III) is successful, data to 1.0 Å resolution is collected for an initial structure solution as shown in stage IV. The final stage is to obtain a full sphere of data to ca 0.84 Å resolution (stage V) for publication from which the final structure is refined.

The key step in solving the crystal structure is to find the correct unit cell (Fig. 1, stage III). In this regard, success is more likely when the sample contains a small number of larger crystals rather than a large number of smaller ones. Initially, the sample is screened by collecting a few frames of diffraction data. Frames that exhibit fewer diffraction spots and diffraction spots to high angle (1 Å resolution or better) are indicative of a sample containing a small number of large crystals, whereas frames that exhibit a large number of spots (and which often lie in powder diffraction rings) are unlikely to yield sensible unit-cell solutions. Examples of data from usable and unusable frames are shown in Fig. S2.

If the sample is composed of only small crystals, several strategies are available. In order to encourage the growth of larger crystals, the sample can be warmed to just below the melt and annealed. This can promote the dissolution of smaller crystallites and growth of the larger ones. In addition, slow translation of the axis of the capillary through the cold gas of the Cryojet5 is facilitated by manual adjustment of the z axis of the goniometer head. Translation through this temperature gradient promotes crystal growth and the sample is re-screened.

Even with a sample containing large crystals, it is usually necessary to collect more screening frames than the typical 10 or 20 measured in a conventional single-crystal experiment in order to find potential unit cells. In our experience, software tools such as CrysAlis PRO can find chemically sensible unit cells from as little as ca 10% of the total number of diffraction peaks measured, but this percentage can be expected to reduce further in future with the introduction of the improved algorithms in programs such as DAFi (Aslandukov et al., 2022). Peak-search software identifies the position of the diffraction peaks and these may be plotted in reciprocal space using tools such as the Ewald Explorer within CrysAlis PRO along with suggested unit cells (see Fig. S3). Unit cells attributed to genuine periodicity in reciprocal space can be identified from sharp peaks seen in the distribution histograms along the a*, b* and c* directions (see Fig. S4). In addition, a clear reciprocal lattice of spots should be observed when the unindexed (or `wrong' spots) are removed from the display (see Figs. S4 and S5). Furthermore, only unit cells with reasonable unit-cell volumes consistent with combinations of the molecular volumes of the components need to be considered.

Finally, indexing solutions with unit cells with two or more cell angles of 90° (and with symmetry higher than triclinic) are often indicative of a cell that is crystallographically likely and which is improbable by random indexing of the spots. Finding the correct unit cell is the hardest step in the whole process since this is analogous to looking for the proverbial `needle in a haystack' but not knowing a priori the shape of the needle. Obviously, once the structure has been solved, finding the correct unit cell again in a screening set of frames is relatively trivial.

Once a unit cell has been identified, a small amount of data can be collected to a resolution of ca 1 Å and the data processed to obtain the F²(hkl) required for an initial structure solution using SHELXT (Fig. 1, stage IV). This whole process can be performed simply with built-in tools such as `What is this?' in CrysAlis PRO, though we stress that it can be achieved easily by the crystallographer manually. Once a chemically sensible structure is obtained, the next step is to collect a full sphere of data to the minimum IUCr d-spacing resolution specification (Fig. 1, stage V). We choose to measure a full sphere to improve data reliability with regard to detrimental effects from absorption and accidental peak overlap. Although in principle software can process data from multiple crystals, in practice we found that processing the data from the one crystal that produces the most spots, and especially with spots at high angles, works best as this will correspond to the largest crystal in the multigrain sample. In principle, data from smaller crystals in the beam may be analysed and the data merged, but this may not improve the overall quality of the data significantly. In our approach, data from the smaller crystals is simply binned. In addition, when using a capillary that is wider than the X-ray beam, a crystal that produces a full sphere of spots is likely to correspond to one that is fully bathed by the beam. The final step is to refine the crystal structure from conventional single-crystal diffraction data.

3.2. The scientific problem

In order to test our hypothesis concerning the applicability of a multigrain approach with laboratory Cu Kα X-ray diffraction data, we investigated co-crystals of C₆F₆ with aromatic heterocyclic co-formers. We have been investigating such systems to probe weak, non-covalent interactions. This is achieved by combining neutral organic molecules with positive (C₆F₆) and negative [e.g. benzene C₆H₆, p-xylene C₆H₄Me₂, ferrocene FeCp₂ where (Cp = C₅H₅)] molecular quadrupolar moments, so as to maximize the electrostatic interaction between faces of the aromatic rings and thus generate a face-to-face pairing of the planar molecules, which can lead to closely packed columns of alternating molecules. Our previous report into the isolation and discovery of the C₆F₆:FeCp₂ co-crystal demonstrated the viability of the columnar stacking of five and six-membered aromatic systems into binary adducts (Bear et al., 2020).

Therefore, we sought to determine whether five-membered aromatic heterocycles would exhibit similar columnar stacking behaviour when used as a co-former with C₆F₆. Prima facie evidence suggested that pyrrole (C₄H₅N) would be an ideal candidate. Pyrrole is an air-stable, five-membered aromatic heterocycle with a negative molecular quadrupole moment, whose magnitude is expected to be comparable to the positive molecular quadrupole moment of C₆F₆ (+32 × 10⁻⁴⁰ C m²) determined by Battaglia et al. (1981). In our previous studies, the co-formers chosen have a dipole moment equal to either zero or a small positive value, e.g. toluene with a moment equal to 0.33 D (Cumper et al., 1969). By contrast, owing to the presence of the highly electronegative nitro­gen heteroatom in the aromatic ring, pyrrole possesses a large dipole moment of 1.74 D (Bohn et al., 1989).

In our SCXRD experiments, a 1:1 molar ratio of C₆F₆:C₄H₅N (as a liquid mixture) was added into a Ø = 0.4 mm capillary and cooled in situ with the Cryojet5 on the X-ray diffractometer to 230 K; this temperature was chosen as it is below the freezing points of the pure components. Moreover, the SCXRD is equipped with a camera, so real-time observation of freezing is possible (Fig. 1, stage I). The sample was then melted and re-frozen, before being increased to 260 K (just below the melting point at 266 K) to allow a degree of `annealing' in order to grow larger (single) crystallites. It is noteworthy that in this study both co-formers are liquid at room temperature. If there is a significant difference in melting point of the two co-formers, then it may be possible to dissolve one co-former into the other, e.g. as in the formation of C₆F₆:Fe(C₅H₅)₂ from Fe(C₅H₅)₂ dissolved in an excess of C₆F₆ (Bear et al., 2020). However, this approach works well when the adduct can be isolated, but becomes problematic when the excess of the co-former solvent is frozen at low temperature leading to additional X-ray diffraction scattering.

Screening of the sample revealed multiple single crystals (Fig. 1, stage II); however, the software was able to identify a monoclinic unit cell with a volume equal to 1795 ų based on as few as 12.5% of the spots, and a cell which is unlikely to occur by random indexing of the spots. However, the relatively large volume of 1795 ų, which suggested approximately seven molecules per unit cell (assuming a volume of around 160 ų for C₆F₆ and 90 ų for C₄H₅N), was less encouraging. Nevertheless, the `What is this?' function was used to find an approximate solution for the structure using this cell (Fig. 1, stage III). Surprisingly, it was found that the structure crystallized in a 3:4 molar ratio of C₆F₆:C₄H₅N despite the 1:1 molar ratio mixture from which the crystals were grown (Fig. 1, stage IV). Thus, the result is consistent with the number of molecules per unit cell determined from the cell volume of 1795 ų. A full sphere of data was then collected to 0.84 Å at 254 K and subsequently at 150 K (Fig. 1, stage V). Details of the data processing and crystal structure refinement are given in the supporting information, with full crystallographic details in Tables S1(a)–S1(e) and in the deposited CIF. The crystal structure of (C₆F₆)₃:(C₄H₅N)₄ at 150 K is shown in Fig. 2.

Figure 2 Refined crystal structure of (C6F6)3:(C4H5N)4 in space group P21/n at 150 K viewed down b. Thermal ellipsoids are shown at 50% probability using the program Mercury from the CCDC (Macrae et al., 2008). The dashed lines in cyan show the closest contacts as identified by Mercury. The crystallographic labelling of the atoms is shown in Fig. S6.

Once the full sphere of data was collected at 150 K, the peak search and auto unit-cell determination identified a similar unit cell to that found at 254 K with about 13% of the total diffraction spots attributable to just one crystal. Data reduction resulted in processing a value of R_int equal to about 10%. With the multigrain approach, a degree of random overlap of diffraction spots from other crystals is expected and this may lead to higher than normal values of R_int. In this instance, where the crystals of (C₆F₆)₃:(C₄H₅N)₄ were grown from a solution containing the components in an incorrect ratio, so that excess C₆F₆ is present, there is a greater degree of overlap of diffraction spots from solid C₆F₆. However, the relatively high value of R_int obtained does not result in a poor crystal structure and, consequently, we considered that there was no need to repeat the experiment with a sample containing the constituents in the correct 3:4 ratio.

The high quality of the structure determination is shown by the values of the bond lengths and angles obtained for the C₆F₆ and C₄H₅N rings [Tables S1(d) and S1(e)]: the average values of the C—C and C—F bonds in C₆F₆, namely 1.372 (5) and 1.337 (5) Å, respectively, are comparable to those observed in pure C₆F₆ at 132 K, namely 1.382 (2) and 1.332 (2) Å (Rusek et al., 2020). The flatness of the aromatic hexagonal ring is demonstrated by the average internal (C—C—C) bond angle of 120.0 (4)°, which is equal to the ideal value of 120°, average torsion angles very close to 0 or 180°, and mean plane deviations for the two rings in the asymmetric unit equal to 0.002 and 0.008°. By comparing the C—C and C—N bond lengths in the C₄H₅N ring with those determined previously for pure C₄H₅N at 103 K (Goddard et al., 1997), we found the average deviation is only 0.022 Å; furthermore, the average sum of the internal angles within the pentagonal ring of 540° is a perfect match for that expected for a flat pentagonal ring, as is the average ring torsion angle of 0.4 (2)° with mean plane deviations (excluding hydrogen atoms) for the two rings in the asymmetric unit equal to 0.002 and 0.003°. In addition, the quality of the data is such that all ten hydrogen atoms for the two crystallographically distinct pyrrole rings in the unit cell are observed as the ten highest peaks in the difference Fourier map (as shown in Fig. S7) and all ten hydrogen atoms can be refined as independent isotropic atoms without the need for constraints.

The crystal structure formed by C₆F₆ and C₄H₅N is not of the adduct type as observed in crystal structures like C₆F₆:C₆H₆ (Cockcroft et al., 2018) but shows a mixture of face and edge interactions between the aromatic rings. It is interesting to compare the interactions between pyrrole rings in this co-crystal with those observed in the solid structure of pyrrole (Goddard et al., 1997). In pyrrole, the molecules interact to form zigzag chains linked by an `N—H⋯π hydrogen bonding' interaction whereas in (C<sub>6</sub>F<sub>6</sub>)<sub>3</sub>:(C<sub>4</sub>H<sub>5</sub>N)<sub>4</sub> the pyrrole molecules assemble into distinctive tetramer units in which the hydrogen on each nitrogen atom is directed more towards the centre of the neighbouring pyrrole ring (see Fig. S8). This raises the interesting question of whether such units form in the liquid phase. In these tetramer units, the molecular dipoles are opposed such that the net dipole is zero. In addition to the pyrrole self-interactions, there is also an orthogonal interaction between the edges of C<sub>6</sub>F<sub>6</sub> rings. Note that in pure C<sub>4</sub>H<sub>5</sub>N and in (C<sub>6</sub>F<sub>6</sub>)<sub>3</sub>:(C<sub>4</sub>H<sub>5</sub>N)<sub>4</sub> there is no possibility for a `donor N—H⋯acceptor' type interaction. Electron density and Hirshfeld 3D surface maps were calculated with the program CrystalExplorer (Spackman et al., 2021) (Fig. S9). The electron density calculated was close to what might be anticipated, showing the expected deviations from the pure compounds as a result of the intermolecular interactions between them that form the co-crystal. The Hirshfeld surface is particularly useful in illustrating the closest contacts between the rings.

DSC data on a freshly prepared sample of (C₆F₆)₃:(C₄H₅N)₄ with components in the correct 3:4 ratio demonstrated the absence of phase transitions as a function of temperature (Fig. S10) in contrast to a number of similar systems we have studied (Cockcroft et al., 2017, 2018, 2019). When phase transitions are present, the multigrain approach as used here may still be useful, e.g. when one or more crystals breaks into several smaller pieces, though in other instances the diffraction data resulting from it may exhibit broader peaks due to mosaic broadening from stress and/or strain effects. In some cases, twinning of the crystals on going through a low-temperature phase transition may present an additional problem. Under such circumstances, it may not be possible to obtain reliable peak intensities I(hkl) from the data frames as the diffraction spots become smeared out around the path of Debye–Scherrer diffraction rings.

3.3. Wider application

The successful structure determination of the co-crystal (C₆F₆)₃:(C₄H₅N)₄ posed several questions: would a mixture of C₆F₆ with other nitro­gen-containing monoheterocyclic aromatic rings form a co-crystal, and could we demonstrate that our laboratory multigrain approach could be used more widely, for example, with co-formers that are likely to form a columnar adduct which typically exhibit acicular crystal forms?

3.3.1. C₆F₆:C₅H₅N

Pyridine (C₅H₅N) is a liquid at room temperature and, like pyrrole, possesses a large dipole moment (2.12 D; Linde, 2004) with a negative quadrupole moment, again whose magnitude is expected to be comparable to the positive quadrupole moment of C₆F₆ (+32 × 10⁻⁴⁰ C m²). As for our initial preparation of a sample of pyrrole:hexa­fluoro­benzene, a 1:1 molar mixture was prepared and inserted into an X-ray capillary. In light of previous experiments, one experimental improvement considered was the use of a narrower 0.2 mm capillary as shown in Fig. S11 so that there is less risk of the X-ray beam hitting a large crystal on the inner wall of the capillary, which may not be fully bathed by the beam in all orientations. Previously, we had used wider capillaries as they are easier to fill. However, a commercial capillary centrifuge enables liquid to be forced more easily to the end of a narrow capillary. This approach reduces the amount of sample in the path of the X-ray beam and potentially helps unit-cell identification by reducing the number of diffracting crystals in the beam. Details of the experimental procedure, data processing and crystal structure refinement are given in the supporting information, with full crystallographic details in Tables S2(a)–S2(e) and in the deposited CIF. The crystal structure of C₆F₆:C₅H₅N at 150 K is shown in Fig. 3.

Figure 3 Refined crystal structure of C6F6:C5H5N in the space group P212121 at 150 K viewed down a. Thermal ellipsoids are shown at 50% probability using the program Mercury from the CCDC (Macrae et al., 2008). Crystallographic labelling of the atoms is provided in Fig. S12.

This material proved more tractable regarding structure solution from a multigrain sample, in part due to a smaller capillary, but also due to the fact that the solid proved to be a 1:1 co-crystal. After screening the crystal, the software suggested a higher symmetry cell than for (C₆F₆)₃:(C₄H₅N)₄ and with a volume of just 1090 ų, consistent with four units of C₆F₆:C₅H₅N in a primitive orthorhombic cell. A full sphere of data was then collected to ca 0.84 Å at 200 K and subsequently at 150 K. For the data at 150 K, the value of R_int (equal to about 6%) was significantly better than that obtained for (C₆F₆)₃:(C₄H₅N)₄. It is noteworthy that the quality of the refined crystal structure of C₆F₆:C₅H₅N is broadly similar to that of (C₆F₆)₃:(C₄H₅N)₄, with mean plane deviations for the C₆F₆ and C₅H₅N rings equal to 0.006 and 0.002°, respectively.

The structure formed by C₆F₆ and C₅H₅N is a 1:1 co-crystal, but is also not columnar in nature. Although the structure is not centrosymmetric, the orthorhombic space group symmetry of P2₁2₁2₁ results in a net dipole moment of zero for the pyridine molecules. Further, there are no particularly close contacts and there is no possibility for an N—H donor⋯acceptor-type interaction due to the absence of a donor hydrogen on the heteroatom. As for the co-crystal formed by hexa­fluoro­benzene and pyrrole, electron density and Hirshfeld 3D surface maps were calculated for hexa­fluoro­benzene and pyridine and showed nothing unexpected (Fig. S13).

3.3.2. p-C₆H₄Me₂:C₆F₅H

To further demonstrate the wider applicability of the method outlined herein, we chose to analyse a potential columnar adduct system between two co-formers, namely penta­fluoro­benzene (C₆F₅H) and p-xylene, where the crystal form is expected to be non-block-like in contrast to the previous examples. We previously studied p-C₆H₄Me₂:C₆F₆ which exhibits two order–disorder solid-state phase transitions at low temperature (Cockcroft et al., 2019). Here we demonstrate that our method may still work even when the crystals have been taken through a phase transition and when the crystal system is triclinic. Identifying the correct unit cell under these conditions is more challenging but is still possible. Variable-temperature PXRD data on p-C₆H₄Me₂:C₆F₅H clearly show a phase transition (Figs. S14 and S15), which is also shown in DSC measurements (Fig. S16). Phase I exists between 127 K and the melt at 253 K, with phase II existing below 127 K. Details of the PXRD and DSC experiments are given in the supporting information, along with the SCXRD experimental procedures, data processing and crystal structure refinement. It is noteworthy that the method worked well despite the fact that the data were collected with our older CCD detector prior to the upgrade to the hybrid-pixel photon detector. Full crystallographic details are given in Tables S3(a)–S3(e) and S4(a)–S4(e) and in the deposited CIFs. The crystal structures of the two phases of p-C₆H₄Me₂:C₆F₅H are shown in Fig. 4.

Figure 4 Comparison of the refined triclinic crystal structures of p-C6H4Me2:C6F5H at 160 K (phase I, left) and 120 K (phase II, right) with the molecular column axis set along c. Thermal ellipsoids are shown at 50% probability (except for hydrogen atoms which have a fixed radius) using the program Mercury from the CCDC (Macrae et al., 2008). Both structures are triclinic and centrosymmetric, but on cooling, the C6F5H molecules order leading to a doubling of the structure along the column axis (i.e. the c direction) and loss of the crystallographic centre of symmetry (shown as blue open circles) at the middle of the C6F5H ring. To enable an easier comparison between the two structures as shown here, phase II was refined in space group I1 with a unit cell 4× the volume of phase I. Crystallographic labelling of the atoms is given in Figs. S17 and S18.

Fig. 4 shows disordered C₆F₅H molecules in phase I (in which the hydrogen has six possible positions) and ordered molecules in phase II (in which the hydrogen has just one position), the latter resulting in a doubling of the unit cell along the column axis direction c. The structures shown in Fig. 4 are somewhat idealized: at 120 K the C₆F₅H still has some residual disorder and at 160 K the position of the lone hydrogen atom is not distributed equally on each of the fluorine atom positions (and so cannot be seen in the figure). Nonetheless, the quality of the refined crystal structures of p-C₆H₄Me₂:C₆F₅H in both phases is high and is broadly similar to that of the two previous examples. This is demonstrated by ring flatness, where torsion angles are close to their ideal values, and mean plane deviations which, as determined by Olex2, vary from 0.000 to 0.003 Å in p-C₆H₄Me₂ and from 0.008 to 0.012 Å in C₆F₅H. For the p-C₆H₄Me₂ molecule, the methyl groups are shown to be disordered in phase I and ordered in phase II.

With regard to the phase II to phase I transition in p-C₆H₄Me₂:C₆F₅H, we note that DSC provides an enthalpy of transition of about 0.3 kJ mol⁻¹. This value is of similar magnitude to the low-temperature order–disorder phase transitions observed in C₆H₅Me:C₆F₆ and p-C₆H₄Me₂:C₆F₆, both of which result from changes in orientational order–disorder of the methyl group in these columnar adducts (Cockcroft et al., 2019). This raises the question of whether the ordering of the C₆F₅H molecules along the column axis is coupled to the ordering of the methyl groups in p-C₆H₄Me₂. Since only a single solid-state transition was observed by DSC at low temperature, we postulate that this is indeed the case.