Coordination diversity in hydrogen-bonded homoleptic fluoride–alcohol complexes modulates reactivity

The X-ray structures of fourteen novel fluoride–alcohol complexes with tetrabutylammonium as the counterion show coordination diversity varying from four to two depending on the steric bulk of the alcohol.


Introduction
Atom-economical uorination processes are highly sought-aer, especially those using readily available starting materials and inexpensive uoride sources. The renewed interest in "F À " chemistry has also been driven by the global growth of the radiopharmaceutical industry and the increasing demand for 18 F-uoride based radiochemistry for applications in positron emission tomography. 1 The uoride salt uorite (also called uorspar) is an important industrial chemical for the production of hydrogen uoride, a precursor of many uorine-containing ne pharmaceuticals. 2 In research laboratories, inexpensive anionic uoride sources are increasingly used as an alternative to F + reagents for transition metal-catalyzed reactions leading to C(sp 2 )-F and C(sp 3 )-F bond construction. 3 Examples of metal-free catalytic nucleophilic uorinations with uoride are rare. A remarkable exception is the native uorinase enzyme, with its ability to produce 5 0 -uoro-5 0 -deoxyadenosine from uoride in aqueous medium ( Fig. 1(I)). 4 This unique enzyme increases uoride nucleophilicity within the active site through desolvation for substitution at the preactivated C-center of S-adenosylmethionine (SAM). Single-crystal X-ray diffraction studies of substrate-and product-bound structures revealed that uoride forms two hydrogen bonds to Ser-158 when it binds in the active site. 5 Subsequent substrate (SAM) binding encourages uoride ion dehydration, thereby facilitating nucleophilic uorination. An additional hydrogenbonding interaction of uoride with Thr-80 likely stabilizes the transition state of the S N 2 uorination process. This enzymatic uorination reaction is highly signicant because the use of uoride ion for C-F bond formation is not trivial and is oen met with complications. One challenge is the poor solubility of common uoride salts in organic solvent. Moreover, uoride is strongly basic in its unsolvated form, and solvation through hydrogen bonding typically lowers nucleophilicity. Numerous strategies have been considered to augment the scope of uoride-based chemistry, either by diversifying the range of uoride ion sources or by achieving controlled uoride release in solution from neutral reagents. Our own contribution to catalytic nucleophilic uorination processes established that the use of TBAF(t-BuOH) 4 is critically important in Pd-and Ir-catalyzed uorination of allylic p-nitrobenzoates and carbonates. 6,7 This reagent is by far the most suitable uoride source for these reactions; neither ammonium uoride nor a range of inorganic alkali uorides led to effective product formation ( Fig. 1(IIa) and 1(IIb)).
These ndings raise the question of how hydrogen bonding to uoride inuences reactivity. Such a study may facilitate the development of superior F À reagents by design, and inform the development of a biomimetic uorinase catalyst capable of broad substrate tolerance, with no compromise on efficacy. The ability of uoride to engage in hydrogen bonding has been previously evoked as a parameter that inuences uoride reactivity, 8 but no detailed analysis is available on how the coordination sphere of hydrogen-bonded uoride complexes correlates with reactivity and product distribution (S N 2/E2 selectivity). In 1994, the rst study examining the effect of hydrogen bonding on uoride reactivity was disclosed by Yonezawa and co-workers, who prepared a series of hydrogenbonded TBAF complexes from TBAF(H 2 O) 3 using alcohol solvents as hydrogen bond donors. 9 A study of their reactivity in a model S N 2 reaction with benzyl bromide revealed that the reaction rate was positively correlated with the steric bulk of the alcohol (t-BuOH [ i-PrOH > n-BuOH $ n-PrOH > H 2 O). Kim and co-workers subsequently reported that kinetic reactivity and S N 2 versus E2 selectivity were enhanced when CsF was used in the presence of bulky tertiary alcohols (e.g., t-BuOH, t-Amy-lOH and 3-methyl-3-pentanol) ( Fig. 1(IIc)). 10 In 2008, the same group published the isolation, characterization and X-ray structure of TBAF(t-BuOH) 4 , conrming its solid-state coordination stoichiometry and tetrahedral geometry. 11 These preliminary data encouraged us to further study hydrogenbonding interactions with uoride as tool to rationally tune reactivity. This problem is of fundamental interest, particularly given that Nature has evolved a uorinase enzyme capable of partially desolvating uoride through hydrogen bonding to key residues at the active site to improve nucleophilicity, as discussed earlier. The importance of hydrogen bonding to uoride extends to transformations other than C-F bond formation, including catalytic, stereoselective desilylation. Selected examples include the catalytic kinetic resolution of silyl-protected secondary benzylic alcohols using chiral hydroxyl-terminated polyether catalysts with potassium uoride 12 and the asymmetric acylation of silyl ketene acetals performed in the presence of a dual-function chiral thiourea organocatalyst. 13 These processes are proposed to involve complexes in which uoride is hydrogen-bonded to the polyether or thiourea catalyst.
The paucity of structural data on uoride-alcohol complexes prompted us to examine in detail the coordination chemistry of uoride-alcohol complexes with the aim of determining how structure correlates with reactivity. Complex formation between halide anions and alcohols has been investigated by gas-phase experimental methods 14 and computational techniques. 15 Compared to other halides, the uoride ion stands out with the largest bonding enthalpies and the shortest X/H hydrogenbond lengths with various hydrogen-bond donors. Detailed information on the structural properties in the solid state for complexes of uoride with alcohols other than phenol derivatives and t-BuOH is surprisingly lacking. 16 Herein, we disclose the synthesis of fourteen new uoride-alcohol complexes and their full characterization in the solid state using single-crystal X-ray diffraction. We also present data on the relative reactivity of these uoride ion complexes towards a model reactant, demonstrating their potential as useful uoride reagents in organic synthesis. Many of these new complexes are easy to handle solids that are less hygroscopic than TBAF(H 2 O) 3 and TBAF(t-BuOH) 4 .

Results and discussion
Overview The alcohols in this study were chosen on the basis of varying steric bulk, in order to elicit a range of coordination geometries in the solid state. The complexes were prepared in good yields by adapting an established synthetic protocol; TBAF(H 2 O) 3 was combined with the alcohol (1-4 eq.) in vigorously reuxing hexane for 2 h. The ensuing crude solid materials were characterized by 1 H and 13 C NMR, and recrystallized as appropriate to obtain single crystals suitable for X-ray diffraction studies (vide infra). Tetra-alkylammonium uoride precursors other than TBAF(H 2 O) 3 (e.g., TMAF and TEAF) were not studied in detail because the resulting alcohol complexes were found to be more difficult to handle and crystallize. All alcohols examined gave either tetra-, tri-, or dicoordinate uoride-alcohol complexes, with the coordination number decreasing as the degree of branching and steric bulk of the alcohol increased. This variability in coordination stoichiometry had not been observed previously (Table 1).

Fluoride complexes with four ROH ligands
The only closely relevant structure preceding this work is that of the tetra-alcohol complex TBAF(t-BuOH) 4 . 10 Accordingly, the tertiary alcohol 1-adamantanol 1a, which is nearly isosteric with t-BuOH around the hydroxyl group but has distinct packing requirements, was examined. Crystallisation of the uoride complex 2a and X-ray diffraction (see Experimental section) gave the anion structure shown in  despite the difference in steric bulk and hydrophobicity of the alcohol hydrogen-bond donors in the two cases. Structures in this class may be analysed for deviations from a formal tetrahedral structure and T d symmetry. 17 Within the coordination sphere, four F/O distances and six O/F/O angles can be measured, as in Fig. 2. For an individual complex, the O/F distances generally do not vary widely and pairs of chelating diols in a 2 : 1 complex exhibit similar bite angles that constrain two of the six angle parameters.
The tetra-(1-adamantanol) complex 2a is the only tetracoordinate structure in this study that does not involve a chelating diol. Consider more generally the three possible coupled-pair distortions from a pure T d structure shown in Fig. 3, which represents a structure for which two angle parameters are constrained by bis-chelation and all distances from the central atom are equal. Any possible geometry may be realised by a combination of three movements of one pair, keeping the second stationary. These three modes can be identied as twist A, roll B and glide C. Using this analysis, the two independent molecules in the unit cell of complex 2a may both be fully described by simply imposing a slight C 2 distortion A on the T d model so that two of the O/F/O angles become smaller than the remaining four. 18 For chelating diol-based structures, the results are more diverse (Fig. 4).
The three 1,3-diol based structures that were obtained form a closely related set in molecular terms but exhibit distinct coordination modes. The most clear-cut case is 2b, derived from pentaerythritol 1b. This 2 : 1 uoride complex crystallized as its DCM solvate, forming a one-dimensional linear hydrogenbonded coordination polymeric structure (Fig. 4a) The individual F(diol) 2 units of the 1D ribbons experience a simple C 2 twist A from an ideal orthogonal geometry, resulting in an interplanar angle between the two O/F/O units of 50.54 (12) .
For the structure of complex 2c, derived from triol 1c (Fig. 4b), two hydrogen bonds to uoride per 1c molecule were observed, with the third hydroxyl group forming an additional hydrogen bond that activates and shortens the neighbouring O-H/F bond. At 81.32 (6) , the plane between the pairs of O/F/O angles of the chelates is close to that of an undistorted tetrahedron. In effect however, through roll and glide motions B and C, one of the two donor -OH groups from one diol remains approximately in its tetrahedral position while the other diol has been rotated away, leading to an arrangement where one oxygen is in the O/F/O plane of the rst diol ligand.
The third member of the series, 2d derived from neopentyl glycol 1d, is again distinct, possessing four different O/F/O distances, as shown in Fig. 4c. The two chelate units are close to coplanarity with an interplanar angle of 11.51(8) but further modied by a signicant contribution of roll distortion B. Alcohol  Three ostensibly similar uoride anion complexes with the same counterion thus show quite distinct geometrical parameters. The variation observed points to a structural model for which the overall lattice geometry is primarily determined by the TBAF cation and the alcohols, with uoride ion demonstrating a capacity to t within that structure. The O/F distances, however, vary only to a small extent in any given structure. Fig. 5 illustrates these tendencies for the three structures discussed above. Viewing the structures through an axis between the central C-C bonds emphasises the marked variation in uoride ion location relative to its ligands.
Three analogous 1,2-diol complexes were prepared, and their crystal structures were analysed similarly. Complex 2e, derived from the enantiomerically pure hydrogen-bond donor (R,R)-diisopropyl tartrate 1e, was crystallized as a hexane solvate. The anion in the ensuing 2 : 1 complex is C 2 -symmetric with the two O/F/O planes oriented at 60.05(7) to one another. In this geometry the two central C-C bonds are very nearly coplanar, with the F atom close to equidistant from the carbon atoms of these bonds and just 0.1391(11)Å from their mean plane. The basic geometry of the complex is imposed by its overall C 2 symmetry (Fig. 6a).
The related complex 2f, derived from 1,2,5,6-(R,S,S,R)-diisopropylidene mannitol 1f, crystallized as an EtOAc solvate. This structure also possesses local C 2 symmetry about the anion, and here the interplanar twist of the two O/F/O subunits is very similar to 2e at 61.03(5) . The actual geometry, however, is quite distinct from 2e through substantial rolling distortion. When one subunit is aligned in plane, the oxygen atoms of the other subunit are respectively 0.7222(8)Å above and 1.7874(9)Å below that plane. The central C-C bonds of the two ligands are no longer co-planar (Fig. 6b).
More signicant structural variation was observed in the complex 2g, derived from pinacol, where two of the four O/F distances are equal to one another and distinct from the remaining two. Here the twist angle between the two O/F/O subunit planes is 64.96(8) , but all four OH ligands are now clearly conned to one coordination hemisphere (Fig. 6c). With respect to one subunit plane, the oxygen atoms of the second diol ligand are respectively 0.7417(13)Å and 2.3880(13)Å, both below that plane. If the subunit planes are created directly from the hydroxyl H/F/H positions, they still occupy a single hemisphere. In order to pursue this observation further, the corresponding tetraethylammonium and tetramethylammonium complexes were synthesized, but both resisted attempts to prepare X-ray diffraction quality crystals.

Fluoride complexes with three ROH ligands
For complexes where the alcohol is sufficiently bulky to permit just three or fewer O-H/F bonds to uoride, different patterns emerge depending on the alcohol structure (Fig. 7).
There is a tendency towards alternative bonding modes that permit higher coordination numbers. 16a For the (R)-binol 2 : 1 complex 2h shown in Fig. 7a, three different molecules participate in bonding to a single uoride ion as part of an extended network linked by interligand hydrogen bonding. This results in a attened tetrahedral geometry for uoride with an unoccupied site, where F À is 0.6501(6)Å distant from the plane described by the three alcohol oxygens. There is an ortho-aryl C-H close to the fourth apex with a C/F distance of 3.3398(12)Å, but it is not well directed for hydrogen bonding (C-H/F ¼ 125.59(3) ).
Trimethylisobenzofuran-2-ol 1i forms complex 2i shown in Fig. 7b. The three-ligand motif is modied here by incorporation of a single ligating water molecule; the resulting structure is close to tetrahedral with all O/F/O angles between 90 and 120 and with uoride ion 0.8942(8)Å out of the plane of the  three oxygen atoms of the donor groups. The hemiacetal is chiral, although the complex crystallizes in an achiral space group. Thus, each individual anion has alternatively (R,R,S) or (S,S,R) conguration. There are two independent motifs in the crystal structure of the 9-phenyluoren-9-ol 3 : 1 complex 2j, with respectively three and two donor alcohols per uoride ion (Fig. 7c). The rst 2j-reg is approximately T-shaped with O/F/O angles of 160.40(4) , 120.00(4) and 78. 30(3) , and the uoride ion is just 0.1325(8)Å out of the plane of the three oxygen donor atoms; the second 2j-alt is discussed below. The 3 : 1 diphenylmethanol complex 2k falls into this group, with the three donor oxygens as part of a attened tetrahedron with the uoride 0.6483(11)Å out of plane (Fig. 7d). The remaining apex is occupied by an a-C-H bond from the TBA cation, with a C/F distance of 3.3331(18)Å, and a C-H/F angle of 161.92(4) .

Fluoride-alcohol complexes with two ROH ligands
Dicoordinate complexes of uoride ion are observed as the sole structural unit only in the bulky triarylmethanol complexes 2l  and 2m, and as the alternative structural motif found in the unit cell of 2j (2j-alt). In the rst of these (2l), the O/F/O angle is 102.94(4) , augmented by donation from an a-C-H of the cation, for which the C/F distance is 3.181(12)Å; the C/F vector makes angles of 117.3(3) and 133.8(3) with the two coordinated O-atoms (Fig. 8a). There are further weak hydrogen bonds from two ortho-C-H atoms of proximal phenyl groups, where the corresponding C-atoms are 3.247(2)Å and 3.2945(18)Å distant from uoride and the spatial orientation is favourable. 19 These two phenyl rings are well ordered whilst the remaining four exhibit librational disorder. For 2m, there are two closely related alcohol-complexed anions in the crystal, and both show the same characteristic features as 2l, with an O/F/O angle of 85.21(3) and a C/F distance of 3.0983(14)Å from one of the C-H groups a to nitrogen in the rst crystallographically distinct equivalent cation (Fig. 8b). These parameters are respectively 87.63(3) and 3.1207(14)Å in the otherwise similar second anion. This is the least coordinated example in the series and is also the most reactive nucleophile (vide infra).
The second structural motif (2j-alt) in the unit cell of crystalline 2j is dicoordinate, with the third molecule of the alcohol involved in hydrogen bonding to one of the donor ligands, but not to uoride (Fig. 8c). A far wider O/F/O angle is observed, at 151.97(5) .
One further dicoordinate alcohol uoride complex was characterized and provides a distinct category. Unlike the diol complexes discussed above, diol 1n forms crystals of a monohydrated anion, with the water molecule acting as an H-bond acceptor to both hydroxyl groups of a second diol. The secondary amine is not engaged in hydrogen bonding. The geometry of this second diol is almost identical to the rst, such that the assembly renes as a single unit with very similar locations for the water oxygen and the uoride atoms; the two diol ligands are distinct only in the positioning of one phenyl group. Fig. 9 shows the uoride anion location in this complex.
In general, the coordination number of uoride complexes is largely determined by the steric bulk of the ligand but was never less than 2 in the series covered in this paper. In accord with the characterized crystal structures of hydrated uoride ion, 20 an optimum coordination of 4 hydrogen-bonding ligands is observed here. Computational studies suggest that water association up to hexacoordination is feasible. 21 In the two published examples where the hydrated uoride ion is unconstrained by further complexation, the structure of the complexed anion lies between tetrahedral and square planar so that only the twist distortion A from the T 4 structure is involved; the O/F/O interplanar angles in those structures are respectively 35 and 37 .
The larger ligands involved in the present study elicit a far wider structural range. Whilst O/F, and by implication H/F, distances are similar for a given structure, there is a trend towards signicantly shorter values with lower coordination numbers, illustrated in Fig. 10.
With 1,2-and 1,3-diols, the interligand angles vary widely, indicating that the geometry of the coordination sphere is far more strongly inuenced by packing forces than through any predisposition to an ideal tetrahedral geometry. With low coordination numbers, there is a tendency for uoride in these complexes to form weak C-H/F bonds. 22 This is unambiguous for coordination of one or more a-protons of TBAF in three cases; with 2l, 2m, and 2k, the C-H/F angle is 160-166 and the C-F distance is between 3.10 and 3.33Å. Other interactions involving proximal aromatic C-H protons, seen in structures of low coordination number, will contribute to the overall stability of the complex. A striking example is provided by 2l, which  requires the specic orientation of two phenyl rings for optimal C-H hydrogen bonding, where the other phenyl rings in the structure are disordered.

Relative nucleophilic reactivity of ROH uoride complexes
In the original studies of TBAF(t-BuOH) 4 as a uorinating agent, Kim and co-workers examined displacement reactions of 3a and 3b. 9,10 The bromide was less selective than the mesylate and gave mixtures of the alkene 5 and uoride 4 in which the latter predominated. The conditions used in this prior work provided a basis for systematic examination of several of the compounds characterized by X-ray diffraction as described above, as controlled sources of uoride ion acting as nucleophile. The results show a range of reactivity of >100 fold on variation of the hydrogen-bond donor alcohol, as shown in Table 2.
Taking rst the reaction using complex 2m (entry 1), reaction is rapid and the decline in [3b] follows a 2 nd order decay over the rst 600 s, subsequently reacting more slowly. The product is partitioned between S N 2 and E2 pathways, with the dominance of the former increasing slightly over time. Running the same reaction at higher dilution of both components demonstrates dramatic changes that increase reactivity and decrease S N 2 selectivity (entries 2, 3). This is consistent with partial or complete dissociation of the L 2 F À complex to give more reactive LF À , or free F À that becomes kinetically dominant at low concentration. Carrying out reaction with 1 M excess alcohol 1m present (entry 4) gives a slower rate but substantially higher S N 2 selectivity. As a representative of the (ROH) 3 F À class, the 9-phenyluoren-9-ol derived complex 2j reacts 8 times more slowly than 2m and gives a lower proportion of product by the E2 pathway (entry 5). 23 Commercial TBAF(H 2 O) 3 was used as a benchmark of reactivity (entry 6). In CH 3 CN the reaction is relatively unselective between S N 2 and E2 pathways, but occurs with higher S N 2 selectivity in toluene (entry 7). Surprisingly, the t-BuOH complex that proved so useful in allylic uorination, 6,7 proved relatively unselective under these conditions (entry 8).
Interesting contrasts were observed by using uoridechelating diols (entries 9-11). With the pinacol complex 2g, the rate and selectivity are comparable to 2j. For the two 1,3diol complexes 2d and 2c the rates are considerably lower, and the slower 2c provides the highest S N 2 selectivity observed in the series. Inspection of the crystal structure of 2g shows that the O-C-C-O units are gauche with dihedral angles of À68.0(2) and À70.5(2) , similar to the preferred tGg 0 ground state of free pinacol derived by spectroscopy and QM. 24 For neopentyl glycol 1d, the preferred C 2 symmetric GG conformation of the chelating unit, 25 is maintained in the X-ray structures, as preferred in the free diols. Hence there is no evidence of additional strain caused by complexation in either 1,2-diol or 1,3-diol uoride anion complexes. The main structural difference between the 1,2-and 1,3-diol complexes lies in the chelate angle O/F/O that denes H-bonding, which is 68.24(5) and 69.11(5) for the two independent pinacol units in 2g, contrasting with 78.62(4) and 79.12(5) for the typical 1,3-diol complex 2d. If the wider angle in the 1,3diol case is associated with greater stability, then the 1,2-diol complex will dissociate one pinacol more easily and hence create an active nucleophilic entity more readily. This is consistent with the observed 5-10 fold higher reactivity of 2g compared with 2c or 2d.
Overall, there is a correlation between the rates of displacement and the S N 2/E2 selectivity. The clear trend towards reduced S N 2 selectivity with increasing rate can be seen in Fig. 11. Stronger complexation of uoride ion is observed with ureas, and this leads to signicantly slower rates of substitution with 3b and higher selectivity towards formation of product 4. 26

Conclusions
From the large number of studies on nucleophilic uorination, it appears that the nature of the uoride reagent is critical for a particular transformation to succeed; the reasons why one uoride source is superior to another are more oen unknown. As a result, an empirical approach that involves the systematic screen of commercially available F À reagents is typically undertaken when developing nucleophilic uorination processes. This work provides new information on the coordination chemistry and relative reactivity of a range of novel uoride-alcohol complexes; some key ndings are listed below.
(a) The synthesis and characterization by single-crystal X-ray diffraction of fourteen uoride-alcohol complexes derived from alcohols, 1,2-diols, 1,3-diols, triols and tetraols demonstrate that tetra-, tri-, or dicoordinate uoride-alcohol complexes can be formed. This variability in coordination stoichiometry had not been observed previously.
(b) For alcohols, the coordination number to uoride varies from two to four, and decreases as the degree of branching and steric bulk of the alcohol is increased.
(c) Complexes with lower coordination number tend to have shorter O/F (and therefore shorter H/F) distances.
(d) Complexes derived from 1,2-and 1,3-diols display a range of interligand angles; this suggests that the packing forces imposed by the ligand are more inuential than the inclination of uoride to form complexes of tetrahedral geometry. The complex derived from pentaerythrol is unique forming a linear polymeric structure with an interplanar angle between the O/F/O units of 50.54 (12) .
(e) The structural features in the solid state of hydrogen bonded uoride-alcohol complexes provide insight into the ability of these complexes to dissociate in solution; such dissociation releases a more active uoride source that inuences rate and S N 2/E2 selectivity. For uoride complexes derived from chelating 1,2-and 1,3-diols, the ability to dissociate to give an active nucleophilic entity depends on the chelate O/F/O angle that denes hydrogen bonding since this angle inuences complex stability.
(f) In solution at high dilution, the uoride complexes L n F À partially or completely dissociate; as a result, reactivity increases but S N 2 versus E2 selectivity decreases.
(g) Many complexes reported here form crystalline solids that are easy to handle and are less hygroscopic than TBAF(H 2 O) 3 and TBAF(t-BuOH) 4 .
This work has demonstrated that uoride-alcohol complexes display structural diversity in the solid state; this key observation implies that there will be signicant variabilities on the ability of these complexes to dissociate in solution. This observation underscores the importance of structural analysis in the solid state combined with kinetic studies as a platform to understand uoride reactivity. Ongoing work, applying experimental and computational methods, focuses on the examination of a larger range of small-molecule hydrogen-bond donors to activate inexpensive and widely available sources of uoride for applications in synthesis, catalysis and [ 18 F] radiochemistry. [27][28][29][30][31][32][33] Experimental For the preparation of TBAF-alcohol complexes, a ask was charged with TBAF(H 2 O) 3 (1.0 eq.), and the alcohol (1.0-4.0 eq.) was added under an atmosphere of N 2 . Hexane was added, and the mixture was reuxed for 2 h, during which time droplets of water formed on the inside walls of the condenser, before letting it cool to RT. The solid products were collected by ltration, washed with hexane and dried under high vacuum, giving the desired complexes, which were used without further purication. Products were stored under an atmosphere of N 2 . Single-crystals suitable for X-ray analysis were obtained by recrystallization from THF, EtOAc or DCM by reducing solubility in a saturated solution through slow mixing with hexanes using a layering or vapour diffusion technique. See the ESI † for details regarding individual compounds.
Low temperature (150 K) single-crystal X-ray diffraction data, 27 were collected using either a Nonius Kappa CCD diffractometer or an Oxford Diffraction (Agilent) SuperNova A diffractometer and reduced using the appropriate instrument manufacturer supplied soware. 28 Structures were solved using either SIR92, 29 or SuperFlip, 30 and rened using full-matrix least-squares renement with CRYSTALS. 31 In the case of 2m, there was a small amount of diffuse residual electron density believed to be disordered solvent. This was modelled using PLATON/SQUEEZE, 32 within CRYSTALS. On renement of 2g, there was a poor agreement between the observed and calculated structure factor amplitudes. Examination of the data and model using ROTAX, 33 suggested the crystal was a pseudo-merohedral twin that was included in the renement. For further details see the full crystallographic data (in CIF format) which are available as ESI. †