Crystal structures of the hexa­fluorido­phosphate salts of the isomeric 2-, 3- and 4-cyano-1-methyl­pyridinium cations and determination of solid-state inter­action energies

Mague, J.T.; Larrabee, E.; Olivier, D.; Vaccaro, F.; Riley, K.E.; Koplitz, L.V.

doi:10.1107/S2056989018011003

research communications

CRYSTALLOGRAPHIC
COMMUNICATIONS

ISSN: 2056-9890

Volume 74| Part 9| September 2018| Pages 1322-1329

https://doi.org/10.1107/S2056989018011003

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Crystal structures of the hexafluoridophosphate salts of the isomeric 2-, 3- and 4-cyano-1-methylpyridinium cations and determination of solid-state interaction energies

Joel T. Mague,^a ^* Erin Larrabee,^b David Olivier,^b Francesca Vaccaro,^b Kevin E. Riley ^c and Lynn V. Koplitz ^b

^aDepartment of Chemistry, Tulane University, New Orleans, LA 70118, USA, ^bDepartment of Chemistry, Loyola University, New Orleans, LA 70118, USA, and ^cDepartment of Chemistry, Xavier University of Louisiana, New Orleans, LA 70125, USA
^*Correspondence e-mail: joelt@tulane.edu

Edited by W. T. A. Harrison, University of Aberdeen, Scotland (Received 8 June 2018; accepted 1 August 2018; online 24 August 2018)

The synthesis and crystal structures of the isomeric molecular salts 2-, 3- and 4-cyano-1-methylpyridinium hexafluoridophosphate, C₇H₇N₂⁺·PF₆⁻, are reported. In 2-cyano-1-methylpyridinium hexafluoridophosphate, C—H⋯F hydrogen bonds form chains extending along the c-axis direction, which are associated through C—H⋯F hydrogen bonds and P—F⋯π(ring) interactions into stepped layers. For 3-cyano-1-methylpyridinium hexafluoridophosphate, corrugated sheets parallel to [001] are generated by C—H⋯F hydrogen bonds and P—F⋯π(ring) interactions. The sheets are weakly associated by a weak interaction of the cyano group with the six-membered ring of the cation. In 4-cyano-1-methylpyridinium hexafluoridophosphate, C—H⋯F hydrogen bonds form a more open three-dimensional network in which stacks of cations and of anions are aligned with the b-axis direction. Dispersion-corrected density functional theory (DFT-D) calculations were carried out in order to elucidate some of the energetic aspects of the solid-state structures. The results indicate that the distribution of charge within a molecular ionic cation can play a large role in determining the strength of a cation–anion interaction within a crystal structure. Crystals of 2-cyano-1-methylpyridinium hexafluoridophosphate are twinned by a 180° rotation about the c* axis. The anion in 3-cyano-1-methylpyridinium hexafluoridophosphate is rotationally disordered by 38.2 (1)° in an 0.848 (3):0.152 (3) ratio.

Keywords: crystal structure; hexafluoridophosphate; cyanopyridinium salts; hydrogen bonds; DFT calculations.

CCDC references: 1859710; 1859709; 1859708

1. Chemical context

Our interest in the structural features of salts of the cyano-1-methylpyridinium cations (CMP) was generated by the significantly different melting behaviors of 3-CMP chloride and iodide (Koplitz et al., 2003 ). This was attributed to a greater amount of C—H⋯N and C—H⋯X (X = Cl⁻, I⁻) hydrogen bonding in the former, in part because all ions lie on mirror planess in the chloride salt while the cation planes are not parallel in the iodide. As a result, it was estimated that the stabilization is at least 1.9 kcal mol⁻¹ more in the chloride than in the iodide. At that time, relatively few crystal structures of CMP salts had been published so in order to investigate the packing and non-covalent interactions for these cations in the solid state, structures of salts of the 2-, 3- and 4-CMP⁺ cations with a variety of anions including Br⁻ (Kammer et al., 2012b ; Mague et al., 2005 ; Nguyen et al., 2015b ), I₃⁻ (Nguyen et al., 2016 ), I⁻ (Kammer et al., 2012a , 2013 ), ClO₄⁻ (Nguyen et al., 2014 ; Nguyen et al., 2015a ; McCormick et al., 2014 ), NO₃⁻ (McCormick et al., 2013 ; Koplitz et al., 2012 ) and BF₄⁻ (Vaccaro et al., 2015 ) were determined. In addition to structures with parallel sheets as for 3-CMP chloride, ones with interpentrating layers, wrinkled sheets and three-dimensional networks are found. We report here on the hexafluoridophosphate salts of all three cations. More broadly, a better understanding of the manifestations of non-covalent interactions in crystalline organic salts will lead to improved predictions for useful substances in a variety of fields, including materials engineering and targeted drug design. Mapping the crystal structure space for heterocyclic cations in a variety of salts is a very important early step in this overall context.

2. Structural commentary

The molecular structures of 1–3 are unexceptional in that all three feature essentially planar cations and octahedral anions (Figs. 1, 2 and 3, respectively). The interest lies in their differing solid-state structures and interionic interactions. First, 1 crystallizes in the centrosymmetric space group P2₁/n while 2 and 3 are in the non-centrosymmetric space group P2₁2₁2₁. Second, the number of interionic interactions per asymmetric unit is six in 1, five in 2 and four in 3. With no mirror planes present, layer structures are not possible and the cation planes are canted with respect to [100] by ±63.19 (9)° in 1, ±62.29 (8)° in 2 and ±31.41 (8)° in 3. In 2 there is a close approach of the cyano group to the six-membered ring of the cation at x − $[{1\over 2}]$ , −y + $[{1\over 2}]$ , −z + 1 with an N2⋯centroid distance of 3.322 (4) Å and a C7—N2⋯centroid angle of 114.4 (3)°.

Figure 1
Perspective view of 1 with labeling scheme and 50% probability ellipsoids.

Figure 2
Perspective view of 2 with labeling scheme and 50% probability ellipsoids. Only the major orientation of the disordered anion is shown. The cation–anion interaction is indicated by a dashed line.

Figure 3
Perspective view of 3 with labeling scheme and 50% probability ellipsoids.

3. Supramolecular features

In 1, one cation and one anion are associated through C4—H4⋯F6 and C5—H5⋯F5 hydrogen bonds (Table 1) and these units are linked by C1—H1B⋯F6 hydrogen bonds, forming chains extending along the c-axis direction. Pairs of chains are joined by C1—H1A⋯F4 hydrogen bonds and interactions of F5 and F6 with the six-membered rings at −x + $[{1\over 2}]$ , y − $[{1\over 2}]$ , −z + $[{3\over 2}]$ [F5⋯centroid = 3.4794 (17) Å, P1—F5⋯centroid = 105.65 (6)°, F6⋯centroid = 3.3569 (19) Å, P1—F6⋯centroid = 110.59 (8)°] of the cations (Table 1 and Fig. 4). The resulting double chains are further joined into stepped layers by C5—H5⋯F5 hydrogen bonds (Fig. 5).

Table 1
Hydrogen-bond geometry (Å, °) for 1

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
C1—H1A⋯F4ⁱ	0.98	2.40	3.161 (3)	134
C1—H1B⋯F6ⁱⁱ	0.98	2.40	3.307 (3)	154
C4—H4⋯F6ⁱⁱⁱ	0.95	2.41	3.319 (3)	160
C5—H5⋯F5^iv	0.95	2.51	3.409 (3)	158
Symmetry codes: (i) $[-x+{\script{1\over 2}}, y+{\script{1\over 2}}, -z+{\script{3\over 2}}]$ ; (ii) $[x+{\script{1\over 2}}, -y+{\script{3\over 2}}, z+{\script{1\over 2}}]$ ; (iii) $[x+{\script{1\over 2}}, -y+{\script{3\over 2}}, z-{\script{1\over 2}}]$ ; (iv) $[-x+{\script{3\over 2}}, y+{\script{1\over 2}}, -z+{\script{3\over 2}}]$ .

Figure 4
Side view of two cation and anion columns in 1 projected onto (021). C—H⋯F hydrogen bonds are shown as black dashed lines and P—F⋯π(ring) interactions by blue dashed lines.

Figure 5
Packing of 1 viewed along the a-axis direction with C—H⋯F hydrogen bonds shown as dashed lines.

For 2, C1—H1B⋯F4, C2—H2⋯F6 and C6—H6⋯F6 hydrogen bonds (Table 2) form zigzag chains (Fig. 6), which are joined by the close interaction of F1 with the six-membered rings of the cations [F1⋯centroid = 3.186 (3) Å, P1—F1⋯centroid = 123.67 (12)°, forming corrugated sheets parallel to [001]. These sheets are associated through the weak interaction of the cyano group with the six-membered ring of the cation mentioned in the preceding section (Fig. 7).

Table 2
Hydrogen-bond geometry (Å, °) for 2

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
C1—H1B⋯F4ⁱ	0.98	2.28	3.225 (5)	161
C2—H2⋯F6ⁱ	0.95	2.34	3.253 (4)	160
C6—H6⋯F6ⁱⁱ	0.95	2.53	3.389 (5)	150
Symmetry codes: (i) $[-x+1, y-{\script{1\over 2}}, -z+{\script{3\over 2}}]$ ; (ii) x+1, y, z.

Figure 6
View of two adjacent cation–anion chains in 2 along the c-axis direction with C—H⋯F hydrogen bonds shown by black dashed lines.

Figure 7
Packing of 2 viewed along the b-axis direction. C—H⋯F hydrogen bonds and P—F⋯π(ring) and C≡N⋯π(ring) interactions are shown, respectively, by black, blue and purple dashed lines.

In 3, a relatively open, three-dimensional network structure in which stacks of cations and of anions are aligned with the b-axis direction is generated by C1—H1C⋯F1, C3—H3⋯F3 and C5—H5⋯F5 hydrogen bonds (Table 3 and Figs. 8 and 9).

Table 3
Hydrogen-bond geometry (Å, °) for 3

D—H⋯A	D—H	H⋯A	D⋯A	D—H⋯A
C5—H5⋯F5ⁱ	0.95	2.37	3.247 (2)	153
C3—H3⋯F3ⁱⁱ	0.95	2.46	3.106 (2)	126
C1—H1C⋯F1ⁱⁱⁱ	0.98	2.51	3.208 (3)	128
Symmetry codes: (i) $[-x+{\script{1\over 2}}, -y, z-{\script{1\over 2}}]$ ; (ii) $[-x+1, y+{\script{1\over 2}}, -z+{\script{3\over 2}}]$ ; (iii) $[-x+{\script{1\over 2}}, -y+1, z-{\script{1\over 2}}]$ .

Figure 8
View of two adjacent cation–anion chains in 3 along the a-axis direction with C—H⋯F hydrogen bonds shown by black dashed lines.

Figure 9
Packing of 3 viewed along the b-axis direction. C—H⋯F hydrogen bonds are shown by black dashed lines.

4. DFT studies

Dispersion-corrected density functional theory (DFT-D) calculations were carried out in order to elucidate some of the energetic aspects of the CMP-PF₆ structures. Calculations were carried out at the ωB97X-D/def2-TZVP level of theory (Jurečka et al., 2007 ; Chai & Head-Gordon, 2008 ; Grimme, 2006 ; Schröder et al., 2017 ). Here, all computations are carried out using the SMD (solvation model based on density) model in order to approximate the effect of the crystal environment (Marenich et al., 2009 ). The dielectric constant of the CMP-PF₆ crystals is currently unknown, so a dielectric constant of 4.0 was chosen as a generic value (as has been done in previous studies; Nguyen et al., 2016). Although the interactions under consideration are between molecular cations and anions, and complex stabilization is therefore attributable mainly to electrostatic forces, it is important that all attractive and repulsive forces (induction, dispersion, exchange) be modeled as well as possible. As DFT is known to describe dispersion interactions very poorly, here we have used a model incorporating an empirical dispersion term (-D2) in order to account for this shortcoming (Grimme, 2006). Dispersion plays a substantial role in stabilizing all non-covalent complexes (Riley et al., 2010 ; Johnson et al., 2010 ) and is known to be especially important in larger aliphatic and aromatic molecules (Sedlak et al., 2013 ). It has been shown that the parameterizations of empirical dispersion terms, which are generally established from gas-phase benchmark data, remain essentially unchanged when implicit solvent models, such as SMD, are used (Riley et al., 2007 ).

Electrostatic potentials for the three CMP molecular cations (Fig. 10) and the PF₆⁻ anion (Fig. 11) were obtained at the B3LYP/6-311+G** level of theory. It has been shown that the quality of an electrostatic potential does not strongly depend on the level of theory (DFT or HF) or on the particular basis set used, so long as the basis set is sufficiently large (at least 6-31G*; Riley et al., 2016 ). The most interesting aspect of these electrostatic potentials concerns the molecular cations, for which there are seen to be large shifts in charge density from one part of the molecular ion to another, with the most positive regions having potential values of 140 (1), 109 (2), and 108 (3) kcal mol⁻¹ and the least positive regions having values of 529 (1), 533 (2), and 531 (3) kcal mol⁻¹. This large shift in charge from one region to another is principally attributable to the high electron-withdrawing capacity of the cyano group, resulting in a less positive partial charge in that region of the molecular ion. For all three molecular cations, the most positively charged regions are those neighboring the CMP methyl groups (i.e. the H atoms that are ortho- to the methyl groups), with the exception of the region located between the methyl and cyano groups in 1. As will be discussed below, the anisotropic distribution of charge throughout these molecular cations has significant effects on the strengths of the interactions (Table 4) between these moieties and the PF₆⁻ anions.

Table 4
Cation–anion interaction energies (kcal mol⁻¹)

Compound 1		Compound 2		Compound 3
D—H⋯A	ΔE_int	D—H⋯A	ΔE_int	D—H⋯A	ΔE_int
C1—H1A⋯F4ⁱ	−19.0	C1—H1B⋯F4^iv	−16.6	C5—H5⋯F5^vi	−14.2
C1—H1B⋯F6ⁱⁱ	−15.9	C2—H2⋯F6^iv	−16.6	C3—H3⋯F3^vii	−15.3
C4—H4⋯F6	−15.7	C6—H6⋯F6^v	−17.8	C1—H1C⋯F1^viii	−16.7
C5—H5⋯F5ⁱⁱⁱ	−15.9
Symmetry codes: (i) −x + $[{1\over 2}]$ , y + $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (ii) x + $[{1\over 2}]$ , −y + $[{3\over 2}]$ , z + $[{1\over 2}]$ ; (iii) −x + $[{3\over 2}]$ , y + $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (iv) −x + 1, y − $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (v) x + 1, y, z; (vi) −x + $[{1\over 2}]$ , −y, z − $[{1\over 2}]$ ; (vii) −x + 1, y + $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (viii) −x + $[{1\over 2}]$ , −y + 1, z − $[{1\over 2}]$ .

Figure 10
Electrostatic potential maps (kcal mol⁻¹) for the 4-CMP⁺ (left), 3-CMP⁺ (center) and 2-CMP⁺ (right) cations. Note the large range of 440 kcal mol⁻¹. The strong electron-withdrawing ability of the cyano group results in a significantly less positive partial charge for that part of the molecular ion.

Figure 11
Electrostatic potential map (kcal mol⁻¹) for the hexafluoridophosphate anion. Note the relatively small range of 50 kcal mol⁻¹.

The shortest cation–anion contacts within the crystal structure of 1 are shown in Fig. 12. Here it is seen that three of the molecular cations (shown in cyan, pink, and yellow) have aromatic rings that are coplanar with each other and are quasi-coplanar with three fluorine atoms from the PF₆⁻ anion. In each case, two contacts are made between a cation H atom and one of the quasi-coplanar PF₆⁻ fluorine atoms, although it should be noted that the longest contact in the interaction involving the pink cation (3.59 Å) is substantially longer than all other contacts (2.40–2.62 Å). Two of the shorter contacts involving aromatic hydrogen atoms (cyan, yellow) and one involving a methyl hydrogen atom (purple). The fourth close contact (green) is a stacking interaction involves a 2-CMP cation located in a plane below PF₆⁻ (as depicted), with a short C—H⋯F contact occurring between a methyl H atom and an anion F atom.

Figure 12
2-CMP⁺⋯PF₆⁻ interactions. BLYP-D3/def2-TZVP/SMD interaction energies (kcal mol⁻¹) for these complexes are: −19.0 (green), −16.9 (cyan), −15.9 (purple), and −15.7 (yellow).

Unsurprisingly, among the four cation–anion pairs given in Fig. 12, the stacking contact (green) represents the strongest interaction, with a binding energy of −19.0 kcal mol⁻¹. The strength of this interaction is mainly due to the large area of contact between cation and ion, with three F atoms within a distance of 3.4 Å from the cation. Without knowledge of the electronic density distribution, as reflected in the electrostatic potential, it might be assumed that the strongest interaction among the PF₆⁻ contacts with the three coplanar molecular cations would be that involving the yellow cation, which exhibits the shortest contact distances with the PF₆⁻ anion. Thus, it is somewhat surprising that this interaction is actually predicted to be the weakest among the coplanar interactions, with an interaction energy of −15.7 kcal mol⁻¹. Surprisingly, even the coplanar interaction with only one short H⁺⋯F⁻ contact (purple) exhibits slightly stronger attraction (−15.9 kcal mol⁻¹), while the strongest interaction (−16.9 kcal mol⁻¹) occurs for the cyan cation, whose contact distances are slightly longer than those of the interaction involving the yellow cation.

The counter-intuitive results described above can be explained by considering the distribution of charge on 2-CMP⁺, as reflected in the electrostatic potential. The most positive region of the 2-CMP⁺ cation encompasses the hydrogen neighboring the methyl group and the N—CH₃ bond. Each of the two stronger complexes (cyan, purple) includes a contact between this strongly positive region of the electrostatic potential and a negative F atom. Conversely the shortest contact in the weaker of these complexes (yellow) involves the H atom that is para- to the methyl group, the least positively charged of the aromatic hydrogen atoms.

The details of cation charge distribution are again seen to be important in determining interaction strengths within the crystal structure of 3. In Fig. 13 it is seen that the strongest interaction involves the green 4-CMP⁺ molecular cation (−16.7 kcal mol⁻¹), whose shortest H⁺⋯F⁻ contact (involving a methyl H atom) is the longest (2.51 Å) among the three interactions considered here. The enhanced strength of this interaction, relative to the other two contacts, can be explained by the orientation of the 4-CMP⁺ cation relative to the PF₆⁻ anion. As seen in Fig. 10, the regions neighboring the methyl group on the 4-CMP⁺ cation are significantly more positive than other regions of the molecular ion. It is this highly positive region that forms contact with the PF₆⁻ anion, as shown in Fig. 13. The weakest interaction here involves the pink 4-CMP⁺ cation (−14.2 kcal mol⁻¹), whose closest H⁺⋯F⁻ distance (2.37 Å) is the shortest among all contacts considered here. This contact involves a hydrogen atom that neighbors the 4-CMP cyano group, which is located in a region whose positive charge is relatively low.

Figure 13
4-CMP⁺⋯PF₆⁻ interactions. BLYP-D3/def2-TZVP/SMD interaction energies (kcal mol⁻¹) for these complexes are: −16.7 (green), −15.3 (cyan), −14.2 (purple).

The ordering of the interaction strengths for the two complexes involving the 3-CMP⁺ cations, shown in Fig. 14, are also counter-intuitive. The interaction with the shorter H⁺⋯F⁻ distances (cyan) represents the weaker of the two interactions. The stronger of the two interactions (green) involves the aromatic H atom that is para- to the cyano group, located on the most positive region of the cation. The proximity of this positive region to the anion is likely responsible for the stronger binding of this cation.

Figure 14
3-CMP⁺⋯PF₆⁻ interactions. BLYP-D3/def2-TZVP/SMD interaction energies (kcal mol⁻¹) −17.8 for these complexes are: (green) and −16.6 (cyan).

Results presented here indicate that the distribution of charge within a molecular ionic cation can play a large role in determining the strength of a cation–anion interaction within a crystal structure. It is presumed that careful inspection of electrostatic potentials becomes more important as the size of a cation increases and as strong electron-withdrawing groups, such as cyano groups, are introduced. Although not investigated here, similar trends are likely observed for larger molecular anions.

5. Database survey

In addition to those compounds cited in the Chemical context section, there are 14 other structures in the CSD (Version 5.39; Groom et al., 2016 ) containing cyano-1-methyl pyridinium cations. Of these, ten contain the 4-CMP cation and the other four the 3-CMP cation. Both 3- and 4-CMP[N(SO₂CF₃)₂] are described with the former having a layer structure formed from cation chains involving C—H⋯N interactions between a ring hydrogen atom and the cyano group, which are bound to anion chains by C_ring—H⋯O and C_methyl—H⋯N hydrogen bonds. The layers have the trifluoromethyl groups protruding from one face and the para ring hydrogens from the other. The latter has a three-dimensional network structure in which only the ring hydrogen atoms form C—H⋯O hydrogen bonds, leading to channels along the a-axis direction with the cyano, methyl and trifluoromethyl groups forming the inner edges (Hardacre et al., 2008 ). The co-crystal of 4-CMP[N(SO₂CF₃)₂] with 1-methylnapthalene has corrugated layers of alternating cations and anions with trifluromethyl groups protruding from both faces interspersed with layers of 1-methylnapthalene (Hardacre et al., 2010 ). In 4-CMP[CH₃OSO₃], C—H⋯O hydrogen bonds involving both aromatic and aliphatic H atoms form cation–anion chains along the c-axis direction, which are joined into double layers having the anion methyl groups protruding from both faces by C_methyl—H⋯O hydrogen bonds (Hardacre et al., 2008). A different structure is found in 4-CMP[Co(CO)₄] where pairwise C_ring—H⋯N interactions form dimers that are expanded into cross-linked zigzag chains by C_ring—H⋯O hydrogen bonds with the anions (Bockman & Kochi, 1989 ). Cross-linked, zigzag chains are also found in 4-CMP[ZnI₄], but here the chains are only cations and are formed by C_methyl—H⋯N interactions. The anions serve to cross-link them through C_ring—H⋯I and C_methyl—H⋯I interactions (Glavcheva et al., 2004 ). Another example of a layer structure is in [4-CMP]₂{Cu[S₂C₂(CN)₂]₂} where alternating cation–anion chains are formed with half of the cations and the anions through C_ring—H⋯N hydrogen bonds. The remaining cations use C_ring—H⋯N hydrogen bonds to both cations and anions in the chains to form a three-dimensional network (Wang et al., 2012 ).

The remaining structures feature large anions, but this does not necessarily isolate the cations from each other. In 4-CMP[{HB(3,5-dimethylpyrazolyl)₃}Mo(CO)₃], the cations form dimers as in 4-CMP[Co(CO)₄] and are associated with the anions through C_ring—H⋯O hydrogen bonds as well as a π–π stacking interaction with one of the pyrazolyl rings (Bockman & Kochi, 1992 ). An entirely different structure is seen in {(4-CMP)₂[Cu₄(μ₃-I)(μ-I)₂]}_n where zigzag chains of cations formed by C_ring—H⋯N hydrogen bonds are arranged at right angles to one another between chains of anions and link the latter through C_methyl—H⋯I interactions (Chan et al., 2012 ). Similar zigzag chains of cations are found in {(3-CMP)[Ag₄(μ₄-I)₂(μ-I)₂(μ-I)]}_n but here they are all coplanar in a layer structure where cation and anion layers alternate (Yu et al., 2014 ). Details of the interionic interactions in {(4-CMP)[Ag₂I₃]}_n (Shen et al., 2014 ) and (3-CMP)BPh₄ (Zhu & Kochi, 1999 ) are obscured by considerable disorder.

6. Synthesis and crystallization

2-Cyano-1-methylpyridinium hexafluoridophosphate (1)

To a solution of 2.499 g (1.016 mmol) of 2-cyano-1-methyl pyridinium iodide (Kammer et al., 2013) dissolved in 20 ml of deionized water was added 1.87 g (1.221 mmol) of solid potassium hexafluoridophosphate with stirring. The white solid that precipitated was washed with a small quantity of ice-cold, deionized water and recrystallized from deionized water by slow evaporation under a gentle stream of nitrogen. M.p. 379 K.

3-Cyano-1-methylpyridinium hexafluoridophosphate (2)

This was prepared and crystallized in analogous manner to that for 1 using 2.508 g (1.019 mmol) of 3-cyano-1-methylpyridinium iodide and 1.873 g (1.223 mmol) of solid potassium hexafluoridophosphate. M.p. 394 K.

4-Cyano-1-methylpyridinium hexafluoridophosphate (3)

This was prepared and crystallized in analogous manner to that for 1 using 2.491 g (1.012 mmol) of 4-cyano-1-methylpyridinium iodide and 1.873 g (1.223 mmol) of solid potassium hexafluoridophosphate. M.p. 418 K.

7. Refinement details

Crystal data, data collection and structure refinement details are summarized in Table 5. Crystals of 1 are twinned by a 180° rotation about the c* axis. Trial refinements of this structure with the single-component reflection file extracted from the twinned data set with TWINABS (Sheldrick, 2009 ) and the full 2-component reflection file showed the former to be more satisfactory. The anion in 2 is rotationally disordered by 38.2 (1)° about the F1—P1—F4 axis in an 0.848 (3):0.152 (3) ratio. The two components of the disorder were refined with restraints that their geometries be comparable. H atoms were placed in calculated positions and refined using a riding model: C—H = 0.98 Å with U_iso(H) = 1.5U_eq(C) for methyl H atoms, C—H = 0.95 Å with U_iso(H) = 1.2U_eq(C) for all other H atoms.

Table 5
Experimental details

	1	2	3
Crystal data
Chemical formula	C₇H₇N₂⁺·PF₆⁻	C₇H₇N₂⁺·PF₆⁻	C₇H₇N₂⁺·PF₆⁻
M_r	264.12	264.12	264.12
Crystal system, space group	Monoclinic, P2₁/n	Orthorhombic, P2₁2₁2₁	Orthorhombic, P2₁2₁2₁
Temperature (K)	150	150	150
a, b, c (Å)	6.5296 (5), 15.7145 (13), 9.5550 (7)	7.8484 (2), 10.8964 (2), 11.8669 (3)	8.5293 (6), 8.6264 (7), 13.3589 (10)
α, β, γ (°)	90, 93.327 (4), 90	90, 90, 90	90, 90, 90
V (Å³)	978.78 (13)	1014.85 (4)	982.91 (13)
Z	4	4	4
Radiation type	Cu Kα	Cu Kα	Mo Kα
μ (mm⁻¹)	3.21	3.09	0.34
Crystal size (mm)	0.20 × 0.17 × 0.06	0.26 × 0.19 × 0.15	0.26 × 0.19 × 0.13

Data collection
Diffractometer	Bruker D8 VENTURE PHOTON 100 CMOS	Bruker D8 VENTURE PHOTON 100 CMOS	Bruker SMART APEX CCD
Absorption correction	Multi-scan (TWINABS; Sheldrick, 2009)	Multi-scan (SADABS; Bruker, 2015 )	Multi-scan (SADABS; Bruker, 2015)
T_min, T_max	0.57, 0.84	0.59, 0.65	0.89, 0.96
No. of measured, independent and observed [I > 2σ(I)] reflections	12567, 1895, 1692	15204, 2009, 1970	19081, 2642, 2420
R_int	0.040	0.034	0.033
(sin θ/λ)_max (Å⁻¹)	0.618	0.618	0.686

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.042, 0.115, 1.07	0.036, 0.095, 1.08	0.031, 0.084, 1.13
No. of reflections	1895	2009	2642
No. of parameters	147	160	146
No. of restraints	0	8	0
H-atom treatment	H-atom parameters constrained	H-atom parameters constrained	H-atom parameters constrained
Δρ_max, Δρ_min (e Å⁻³)	0.31, −0.33	0.35, −0.36	0.31, −0.20
Absolute structure	–	Flack x determined using 800 quotients [(I⁺)−(I⁻)]/[(I⁺)+(I⁻)] (Parsons et al., 2013 )	Flack x determined using 988 quotients [(I⁺)−(I⁻)]/[(I⁺)+(I⁻)] (Parsons et al., 2013)
Absolute structure parameter	–	0.040 (6)	−0.01 (3)
Computer programs: APEX2 and SAINT (Bruker, 2015), CELL_NOW (Sheldrick, 2008b ), SHELXT (Sheldrick, 2015a ), SHELXL (Sheldrick, 2015b ), DIAMOND (Brandenburg & Putz, 2012 ) and SHELXTL (Sheldrick, 2008a ).

Supporting information

CCDC references: 1859710; 1859709; 1859708

Crystal structure: contains datablocks New_Global_Publ_Block, 1, 2, 3. DOI: https://doi.org/10.1107/S2056989018011003/hb7755sup1.cif

Structure factors: contains datablock 1. DOI: https://doi.org/10.1107/S2056989018011003/hb77551sup2.hkl

Structure factors: contains datablock 2. DOI: https://doi.org/10.1107/S2056989018011003/hb77552sup3.hkl

Structure factors: contains datablock 3. DOI: https://doi.org/10.1107/S2056989018011003/hb77553sup4.hkl

Supporting information file. DOI: https://doi.org/10.1107/S2056989018011003/hb77551sup5.cml

Supporting information file. DOI: https://doi.org/10.1107/S2056989018011003/hb77552sup6.cml

Supporting information file. DOI: https://doi.org/10.1107/S2056989018011003/hb77553sup7.cml

checkCIF report

Computing details top

For all structures, data collection: APEX2 (Bruker, 2015); cell refinement: SAINT (Bruker, 2015). Data reduction: SAINT (Bruker, 2015), CELL_NOW (Sheldrick, 2008b) for (1); SAINT (Bruker, 2015) for (2), (3). For all structures, program(s) used to solve structure: SHELXT (Sheldrick, 2015a); program(s) used to refine structure: SHELXL (Sheldrick, 2015b); molecular graphics: DIAMOND (Brandenburg & Putz, 2012); software used to prepare material for publication: SHELXTL (Sheldrick, 2008a).

2-Cyano-1-methylpyridinium hexafluoridophosphate (1) top

Crystal data top

C₇H₇N₂⁺·PF₆⁻	F(000) = 528
M_r = 264.12	D_x = 1.792 Mg m⁻³
Monoclinic, P2₁/n	Cu Kα radiation, λ = 1.54178 Å
a = 6.5296 (5) Å	Cell parameters from 2191 reflections
b = 15.7145 (13) Å	θ = 7.3–71.9°
c = 9.5550 (7) Å	µ = 3.21 mm⁻¹
β = 93.327 (4)°	T = 150 K
V = 978.78 (13) Å³	Plate, colourless
Z = 4	0.20 × 0.17 × 0.06 mm

Data collection top

Bruker D8 VENTURE PHOTON 100 CMOS diffractometer	1895 independent reflections
Radiation source: INCOATEC IµS micro–focus source	1692 reflections with I > 2σ(I)
Mirror monochromator	R_int = 0.040
Detector resolution: 10.4167 pixels mm^-1	θ_max = 72.4°, θ_min = 5.4°
ω scans	h = −7→7
Absorption correction: multi-scan (TWINABS; Sheldrick, 2009)	k = −17→17
T_min = 0.57, T_max = 0.84	l = −10→8
12567 measured reflections

Refinement top

Refinement on F²	Secondary atom site location: difference Fourier map
Least-squares matrix: full	Hydrogen site location: inferred from neighbouring sites
R[F² > 2σ(F²)] = 0.042	H-atom parameters constrained
wR(F²) = 0.115	w = 1/[σ²(F_o²) + (0.0632P)² + 0.6053P] where P = (F_o² + 2F_c²)/3
S = 1.07	(Δ/σ)_max < 0.001
1895 reflections	Δρ_max = 0.31 e Å⁻³
147 parameters	Δρ_min = −0.33 e Å⁻³
0 restraints	Extinction correction: SHELXL2014/7 (Sheldrick, 2015b), Fc^*=kFc[1+0.001xFc²λ³/sin(2θ)]^-1/4
Primary atom site location: structure-invariant direct methods	Extinction coefficient: 0.0045 (7)

Special details top

Experimental. Analysis of 2191 reflections having I/σ(I) > 13 and chosen from the full data set with CELL_NOW (Sheldrick, 2008) showed the crystal to belong to the monoclinic system and to be twinned by a 180° rotation about the c* axis. The raw data were processed using the multi-component version of SAINT under control of the two-component orientation file generated by CELL_NOW.

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Refinement. Refinement of F² against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F², conventional R-factors R are based on F, with F set to zero for negative F². The threshold expression of F² > 2sigma(F²) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F² are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger. H-atoms were placed in calculated positions (C—H = 0.95 - 0.98 Å) and included as riding contributions with isotropic displacement parameters 1.2 - 1.5 times those of the attached carbon atoms. Trial refinements with both the single-component data extracted with TWINABS and the full twinned data indicated that the former produced a more satisfactory model.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq
N1	0.4176 (3)	0.86681 (11)	0.80398 (18)	0.0250 (4)
N2	−0.0598 (3)	0.77157 (13)	0.7824 (2)	0.0388 (5)
C1	0.3803 (4)	0.85654 (16)	0.9546 (2)	0.0349 (5)
H1A	0.2619	0.8911	0.9776	0.052*
H1B	0.5018	0.8752	1.0115	0.052*
H1C	0.3527	0.7966	0.9743	0.052*
C2	0.2757 (3)	0.83897 (13)	0.7044 (2)	0.0256 (4)
C3	0.3078 (4)	0.84670 (14)	0.5644 (2)	0.0308 (5)
H3	0.2084	0.8265	0.4957	0.037*
C4	0.4873 (4)	0.88441 (14)	0.5246 (2)	0.0341 (5)
H4	0.5129	0.8899	0.4282	0.041*
C5	0.6281 (4)	0.91379 (14)	0.6259 (3)	0.0350 (5)
H5	0.7506	0.9407	0.6000	0.042*
C6	0.5899 (3)	0.90390 (14)	0.7655 (2)	0.0311 (5)
H6	0.6876	0.9238	0.8355	0.037*
C7	0.0906 (3)	0.80090 (14)	0.7509 (2)	0.0286 (5)
P1	0.42105 (8)	0.58120 (3)	0.73007 (5)	0.0260 (2)
F1	0.3952 (3)	0.66725 (10)	0.81616 (18)	0.0499 (4)
F2	0.6643 (2)	0.59231 (10)	0.74158 (17)	0.0427 (4)
F3	0.4065 (2)	0.63247 (11)	0.58661 (16)	0.0499 (4)
F4	0.4482 (3)	0.49411 (10)	0.64785 (17)	0.0506 (4)
F5	0.4308 (2)	0.52981 (10)	0.87364 (15)	0.0471 (4)
F6	0.1770 (2)	0.56909 (11)	0.71904 (16)	0.0443 (4)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
N1	0.0252 (9)	0.0227 (9)	0.0271 (9)	0.0018 (7)	0.0011 (7)	−0.0016 (6)
N2	0.0349 (12)	0.0336 (11)	0.0478 (12)	−0.0043 (8)	0.0029 (9)	0.0027 (9)
C1	0.0381 (13)	0.0414 (13)	0.0248 (11)	0.0031 (10)	−0.0003 (9)	−0.0011 (9)
C2	0.0264 (11)	0.0195 (9)	0.0307 (10)	0.0033 (8)	−0.0006 (8)	0.0001 (8)
C3	0.0362 (12)	0.0249 (11)	0.0310 (11)	0.0002 (9)	−0.0023 (9)	0.0001 (8)
C4	0.0433 (14)	0.0273 (11)	0.0324 (12)	0.0021 (9)	0.0082 (10)	0.0018 (9)
C5	0.0323 (12)	0.0281 (11)	0.0453 (14)	−0.0012 (9)	0.0093 (10)	0.0001 (9)
C6	0.0273 (11)	0.0267 (11)	0.0391 (13)	−0.0001 (8)	0.0003 (9)	−0.0040 (9)
C7	0.0301 (12)	0.0250 (11)	0.0301 (10)	0.0003 (8)	−0.0033 (8)	0.0009 (8)
P1	0.0283 (3)	0.0249 (3)	0.0248 (3)	0.00132 (19)	0.0022 (2)	0.00086 (19)
F1	0.0546 (10)	0.0339 (8)	0.0603 (10)	0.0116 (7)	−0.0027 (7)	−0.0167 (7)
F2	0.0283 (8)	0.0477 (9)	0.0520 (9)	0.0000 (6)	0.0022 (6)	0.0001 (7)
F3	0.0482 (9)	0.0618 (10)	0.0400 (9)	0.0034 (7)	0.0036 (7)	0.0229 (7)
F4	0.0600 (10)	0.0387 (8)	0.0539 (9)	−0.0024 (7)	0.0104 (8)	−0.0192 (7)
F5	0.0528 (10)	0.0545 (9)	0.0347 (8)	0.0112 (7)	0.0074 (6)	0.0171 (7)
F6	0.0287 (8)	0.0613 (10)	0.0428 (8)	−0.0047 (6)	0.0017 (6)	0.0025 (7)

Geometric parameters (Å, º) top

N1—C6	1.338 (3)	C4—C5	1.375 (4)
N1—C2	1.361 (3)	C4—H4	0.9500
N1—C1	1.482 (3)	C5—C6	1.380 (3)
N2—C7	1.141 (3)	C5—H5	0.9500
C1—H1A	0.9800	C6—H6	0.9500
C1—H1B	0.9800	P1—F3	1.5881 (14)
C1—H1C	0.9800	P1—F5	1.5899 (14)
C2—C3	1.371 (3)	P1—F4	1.5931 (15)
C2—C7	1.442 (3)	P1—F2	1.5953 (15)
C3—C4	1.386 (3)	P1—F1	1.5967 (15)
C3—H3	0.9500	P1—F6	1.6020 (15)

C6—N1—C2	119.82 (19)	C6—C5—H5	120.3
C6—N1—C1	120.14 (19)	N1—C6—C5	121.1 (2)
C2—N1—C1	120.04 (18)	N1—C6—H6	119.4
N1—C1—H1A	109.5	C5—C6—H6	119.4
N1—C1—H1B	109.5	N2—C7—C2	177.1 (2)
H1A—C1—H1B	109.5	F3—P1—F5	178.89 (9)
N1—C1—H1C	109.5	F3—P1—F4	90.74 (9)
H1A—C1—H1C	109.5	F5—P1—F4	89.38 (9)
H1B—C1—H1C	109.5	F3—P1—F2	90.76 (9)
N1—C2—C3	121.1 (2)	F5—P1—F2	90.35 (8)
N1—C2—C7	117.79 (19)	F4—P1—F2	89.37 (9)
C3—C2—C7	121.1 (2)	F3—P1—F1	90.70 (9)
C2—C3—C4	119.0 (2)	F5—P1—F1	89.19 (9)
C2—C3—H3	120.5	F4—P1—F1	178.54 (10)
C4—C3—H3	120.5	F2—P1—F1	90.37 (9)
C5—C4—C3	119.4 (2)	F3—P1—F6	89.67 (8)
C5—C4—H4	120.3	F5—P1—F6	89.23 (9)
C3—C4—H4	120.3	F4—P1—F6	90.24 (9)
C4—C5—C6	119.5 (2)	F2—P1—F6	179.43 (9)
C4—C5—H5	120.3	F1—P1—F6	90.00 (9)

C6—N1—C2—C3	1.3 (3)	C2—C3—C4—C5	−0.5 (3)
C1—N1—C2—C3	−179.1 (2)	C3—C4—C5—C6	1.1 (3)
C6—N1—C2—C7	−178.81 (19)	C2—N1—C6—C5	−0.7 (3)
C1—N1—C2—C7	0.8 (3)	C1—N1—C6—C5	179.7 (2)
N1—C2—C3—C4	−0.7 (3)	C4—C5—C6—N1	−0.5 (3)
C7—C2—C3—C4	179.4 (2)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
C1—H1A···F4ⁱ	0.98	2.40	3.161 (3)	134
C1—H1B···F6ⁱⁱ	0.98	2.40	3.307 (3)	154
C4—H4···F6ⁱⁱⁱ	0.95	2.41	3.319 (3)	160
C5—H5···F5^iv	0.95	2.51	3.409 (3)	158

Symmetry codes: (i) −x+1/2, y+1/2, −z+3/2; (ii) x+1/2, −y+3/2, z+1/2; (iii) x+1/2, −y+3/2, z−1/2; (iv) −x+3/2, y+1/2, −z+3/2.

3-Cyano-1-methylpyridinium hexafluoridophosphate (2) top

Crystal data top

C₇H₇N₂⁺·PF₆⁻	D_x = 1.729 Mg m⁻³
M_r = 264.12	Cu Kα radiation, λ = 1.54178 Å
Orthorhombic, P2₁2₁2₁	Cell parameters from 9953 reflections
a = 7.8484 (2) Å	θ = 3.7–72.4°
b = 10.8964 (2) Å	µ = 3.09 mm⁻¹
c = 11.8669 (3) Å	T = 150 K
V = 1014.85 (4) Å³	Block, colourless
Z = 4	0.26 × 0.19 × 0.15 mm
F(000) = 528

Data collection top

Bruker D8 VENTURE PHOTON 100 CMOS diffractometer	2009 independent reflections
Radiation source: INCOATEC IµS micro–focus source	1970 reflections with I > 2σ(I)
Mirror monochromator	R_int = 0.034
Detector resolution: 10.4167 pixels mm^-1	θ_max = 72.3°, θ_min = 5.5°
ω scans	h = −9→9
Absorption correction: multi-scan (SADABS; Bruker, 2015)	k = −13→13
T_min = 0.59, T_max = 0.65	l = −14→14
15204 measured reflections

Refinement top

Refinement on F²	Hydrogen site location: inferred from neighbouring sites
Least-squares matrix: full	H-atom parameters constrained
R[F² > 2σ(F²)] = 0.036	w = 1/[σ²(F_o²) + (0.0513P)² + 0.5414P] where P = (F_o² + 2F_c²)/3
wR(F²) = 0.095	(Δ/σ)_max < 0.001
S = 1.08	Δρ_max = 0.35 e Å⁻³
2009 reflections	Δρ_min = −0.36 e Å⁻³
160 parameters	Extinction correction: SHELXL (Sheldrick, 2015b), Fc^*=kFc[1+0.001xFc²λ³/sin(2θ)]^-1/4
8 restraints	Extinction coefficient: 0.0095 (11)
Primary atom site location: structure-invariant direct methods	Absolute structure: Flack x determined using 800 quotients [(I⁺)-(I^-)]/[(I⁺)+(I^-)] (Parsons et al., 2013)
Secondary atom site location: difference Fourier map	Absolute structure parameter: 0.040 (6)

Special details top

Refinement. Refinement of F² against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F², conventional R-factors R are based on F, with F set to zero for negative F². The threshold expression of F² > 2sigma(F²) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F² are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger. H-atoms were placed in calculated positions (C—H = 0.95 - 0.98 Å) and included as riding contributions with isotropic displacement parameters 1.2 - 1.5 times those of the attached carbon atoms. The anion is rotationally disordered over two resolved sites about the F1···F4 axis in a 85/15 ratio. The disorder was refined with restraints that the two components have the same geometry.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq	Occ. (<1)
N1	0.9719 (3)	0.3953 (2)	0.6993 (2)	0.0309 (5)
N2	0.5379 (5)	0.3571 (3)	0.4213 (3)	0.0543 (8)
C1	0.9963 (5)	0.3420 (3)	0.8133 (3)	0.0446 (8)
H1A	1.0606	0.2652	0.8073	0.067*
H1B	0.8849	0.3254	0.8475	0.067*
H1C	1.0594	0.4001	0.8606	0.067*
C2	0.8312 (4)	0.3669 (3)	0.6408 (3)	0.0316 (7)
H2	0.7464	0.3157	0.6733	0.038*
C3	0.8100 (4)	0.4122 (3)	0.5329 (3)	0.0318 (7)
C4	0.9332 (4)	0.4882 (3)	0.4868 (3)	0.0376 (7)
H4	0.9196	0.5206	0.4131	0.045*
C5	1.0763 (5)	0.5159 (4)	0.5499 (3)	0.0429 (8)
H5	1.1621	0.5680	0.5198	0.051*
C6	1.0937 (4)	0.4676 (3)	0.6563 (3)	0.0370 (7)
H6	1.1924	0.4856	0.6995	0.044*
C7	0.6579 (5)	0.3806 (3)	0.4718 (3)	0.0396 (8)
P1	0.53561 (10)	0.67446 (7)	0.67835 (6)	0.0304 (2)
F1	0.6869 (4)	0.6015 (3)	0.7338 (2)	0.0688 (8)
F4	0.3803 (3)	0.7456 (3)	0.6233 (3)	0.0786 (9)
F2	0.6590 (4)	0.7059 (3)	0.5769 (2)	0.0553 (8)	0.848 (3)
F3	0.4755 (4)	0.5537 (3)	0.6115 (3)	0.0647 (9)	0.848 (3)
F5	0.5888 (5)	0.7938 (3)	0.7430 (4)	0.0835 (14)	0.848 (3)
F6	0.4049 (4)	0.6385 (2)	0.7769 (2)	0.0522 (8)	0.848 (3)
F2A	0.599 (2)	0.664 (2)	0.5531 (6)	0.0553 (8)	0.152 (3)
F3A	0.481 (2)	0.5344 (7)	0.6895 (17)	0.0647 (9)	0.152 (3)
F5A	0.606 (2)	0.8092 (8)	0.679 (2)	0.0835 (14)	0.152 (3)
F6A	0.4950 (19)	0.6976 (14)	0.8095 (6)	0.0522 (8)	0.152 (3)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
N1	0.0269 (11)	0.0281 (12)	0.0378 (13)	0.0013 (11)	0.0057 (11)	0.0006 (10)
N2	0.0478 (18)	0.0555 (19)	0.0597 (19)	−0.0142 (16)	−0.0071 (18)	−0.0133 (16)
C1	0.0425 (19)	0.0486 (19)	0.0428 (17)	−0.0023 (15)	−0.0016 (15)	0.0112 (15)
C2	0.0278 (15)	0.0254 (13)	0.0416 (16)	−0.0037 (12)	0.0070 (12)	−0.0030 (11)
C3	0.0314 (15)	0.0234 (13)	0.0406 (16)	−0.0029 (12)	0.0030 (13)	−0.0071 (12)
C4	0.0423 (19)	0.0321 (15)	0.0385 (16)	−0.0098 (14)	0.0023 (14)	−0.0003 (13)
C5	0.0374 (18)	0.0435 (19)	0.0477 (19)	−0.0147 (15)	0.0036 (15)	0.0047 (15)
C6	0.0286 (15)	0.0370 (17)	0.0453 (18)	−0.0060 (13)	0.0026 (13)	0.0000 (14)
C7	0.0397 (17)	0.0359 (16)	0.0431 (17)	−0.0079 (14)	−0.0002 (15)	−0.0096 (15)
P1	0.0261 (4)	0.0322 (4)	0.0331 (4)	0.0031 (3)	0.0033 (3)	0.0003 (3)
F1	0.0616 (15)	0.095 (2)	0.0500 (13)	0.0445 (15)	−0.0073 (12)	0.0000 (13)
F4	0.0455 (14)	0.090 (2)	0.100 (2)	0.0266 (14)	−0.0090 (14)	0.0258 (19)
F2	0.0416 (16)	0.078 (2)	0.0465 (14)	−0.0058 (14)	0.0129 (13)	0.0148 (14)
F3	0.0441 (13)	0.0667 (17)	0.083 (2)	−0.0172 (14)	0.0128 (17)	−0.0386 (17)
F5	0.0592 (17)	0.0662 (19)	0.125 (4)	−0.0103 (14)	0.011 (2)	−0.064 (2)
F6	0.0469 (15)	0.0530 (16)	0.0567 (15)	0.0087 (11)	0.0262 (13)	0.0062 (12)
F2A	0.0416 (16)	0.078 (2)	0.0465 (14)	−0.0058 (14)	0.0129 (13)	0.0148 (14)
F3A	0.0441 (13)	0.0667 (17)	0.083 (2)	−0.0172 (14)	0.0128 (17)	−0.0386 (17)
F5A	0.0592 (17)	0.0662 (19)	0.125 (4)	−0.0103 (14)	0.011 (2)	−0.064 (2)
F6A	0.0469 (15)	0.0530 (16)	0.0567 (15)	0.0087 (11)	0.0262 (13)	0.0062 (12)

Geometric parameters (Å, º) top

N1—C6	1.340 (4)	C5—C6	1.375 (5)
N1—C2	1.341 (4)	C5—H5	0.9500
N1—C1	1.485 (4)	C6—H6	0.9500
N2—C7	1.145 (5)	P1—F5	1.567 (3)
C1—H1A	0.9800	P1—F5A	1.569 (6)
C1—H1B	0.9800	P1—F2A	1.572 (6)
C1—H1C	0.9800	P1—F1	1.573 (2)
C2—C3	1.382 (5)	P1—F2	1.582 (2)
C2—H2	0.9500	P1—F4	1.586 (3)
C3—C4	1.385 (4)	P1—F3A	1.590 (6)
C3—C7	1.438 (5)	P1—F6	1.604 (2)
C4—C5	1.383 (5)	P1—F3	1.607 (3)
C4—H4	0.9500	P1—F6A	1.608 (6)

C6—N1—C2	121.7 (3)	F5A—P1—F1	101.8 (8)
C6—N1—C1	119.1 (3)	F2A—P1—F1	96.9 (7)
C2—N1—C1	119.2 (3)	F5—P1—F2	91.7 (2)
N1—C1—H1A	109.5	F1—P1—F2	88.03 (15)
N1—C1—H1B	109.5	F5—P1—F4	90.1 (2)
H1A—C1—H1B	109.5	F5A—P1—F4	79.4 (8)
N1—C1—H1C	109.5	F2A—P1—F4	83.6 (7)
H1A—C1—H1C	109.5	F1—P1—F4	178.71 (18)
H1B—C1—H1C	109.5	F2—P1—F4	92.93 (16)
N1—C2—C3	119.8 (3)	F5A—P1—F3A	172.8 (10)
N1—C2—H2	120.1	F2A—P1—F3A	95.4 (10)
C3—C2—H2	120.1	F1—P1—F3A	71.5 (7)
C2—C3—C4	119.7 (3)	F4—P1—F3A	107.3 (7)
C2—C3—C7	118.8 (3)	F5—P1—F6	90.9 (2)
C4—C3—C7	121.6 (3)	F1—P1—F6	93.12 (15)
C5—C4—C3	119.0 (3)	F2—P1—F6	177.11 (18)
C5—C4—H4	120.5	F4—P1—F6	85.88 (16)
C3—C4—H4	120.5	F5—P1—F3	178.3 (2)
C6—C5—C4	119.5 (3)	F1—P1—F3	90.83 (19)
C6—C5—H5	120.2	F2—P1—F3	88.94 (18)
C4—C5—H5	120.2	F4—P1—F3	88.3 (2)
N1—C6—C5	120.3 (3)	F6—P1—F3	88.39 (17)
N1—C6—H6	119.8	F5A—P1—F6A	85.2 (11)
C5—C6—H6	119.8	F2A—P1—F6A	171.6 (9)
N2—C7—C3	178.5 (4)	F1—P1—F6A	79.9 (5)
F5A—P1—F2A	87.9 (12)	F4—P1—F6A	99.8 (5)
F5—P1—F1	90.8 (2)	F3A—P1—F6A	91.0 (9)

C6—N1—C2—C3	0.3 (4)	C7—C3—C4—C5	179.6 (3)
C1—N1—C2—C3	−177.6 (3)	C3—C4—C5—C6	0.2 (5)
N1—C2—C3—C4	−0.9 (4)	C2—N1—C6—C5	0.5 (5)
N1—C2—C3—C7	−179.9 (3)	C1—N1—C6—C5	178.5 (3)
C2—C3—C4—C5	0.7 (5)	C4—C5—C6—N1	−0.8 (6)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
C1—H1B···F4ⁱ	0.98	2.28	3.225 (5)	161
C2—H2···F6ⁱ	0.95	2.34	3.253 (4)	160
C6—H6···F6ⁱⁱ	0.95	2.53	3.389 (5)	150

Symmetry codes: (i) −x+1, y−1/2, −z+3/2; (ii) x+1, y, z.

4-Cyano-1-methylpyridinium hexafluoridophosphate (3) top

Crystal data top

C₇H₇N₂⁺·PF₆⁻	D_x = 1.785 Mg m⁻³
M_r = 264.12	Mo Kα radiation, λ = 0.71073 Å
Orthorhombic, P2₁2₁2₁	Cell parameters from 9502 reflections
a = 8.5293 (6) Å	θ = 2.8–29.1°
b = 8.6264 (7) Å	µ = 0.34 mm⁻¹
c = 13.3589 (10) Å	T = 150 K
V = 982.91 (13) Å³	Block, colourless
Z = 4	0.26 × 0.19 × 0.13 mm
F(000) = 528

Data collection top

Bruker SMART APEX CCD diffractometer	2642 independent reflections
Radiation source: fine-focus sealed tube	2420 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.033
Detector resolution: 8.3333 pixels mm^-1	θ_max = 29.2°, θ_min = 2.8°
φ and ω scans	h = −11→11
Absorption correction: multi-scan (SADABS; Bruker, 2015)	k = −11→11
T_min = 0.89, T_max = 0.96	l = −18→18
19081 measured reflections

Refinement top

Refinement on F²	Secondary atom site location: difference Fourier map
Least-squares matrix: full	Hydrogen site location: inferred from neighbouring sites
R[F² > 2σ(F²)] = 0.031	H-atom parameters constrained
wR(F²) = 0.084	w = 1/[σ²(F_o²) + (0.0536P)² + 0.0393P] where P = (F_o² + 2F_c²)/3
S = 1.13	(Δ/σ)_max = 0.006
2642 reflections	Δρ_max = 0.31 e Å⁻³
146 parameters	Δρ_min = −0.20 e Å⁻³
0 restraints	Absolute structure: Flack x determined using 988 quotients [(I⁺)-(I^-)]/[(I⁺)+(I^-)] (Parsons et al., 2013)
Primary atom site location: structure-invariant direct methods	Absolute structure parameter: −0.01 (3)

Special details top

Experimental. The diffraction data were obtained from 3 sets of 400 frames, each of width 0.5° in ω, colllected at φ = 0.00, 90.00 and 180.00° and 2 sets of 800 frames, each of width 0.45° in φ, collected at ω = –30.00 and 210.00°. The scan time was 15 sec/frame.

Refinement. Refinement of F² against ALL reflections. The weighted R-factor wR and goodness of fit S are based on F², conventional R-factors R are based on F, with F set to zero for negative F². The threshold expression of F² > 2sigma(F²) is used only for calculating R-factors(gt) etc. and is not relevant to the choice of reflections for refinement. R-factors based on F² are statistically about twice as large as those based on F, and R- factors based on ALL data will be even larger. H-atoms attached to carbon were placed in calculated positions (C—H = 0.95 - 0.98 Å). All were included as riding contributions with isotropic displacement parameters 1.2 - 1.5 times those of the attached atoms.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å²) top

	x	y	z	U_iso*/U_eq
N1	0.3277 (2)	0.58167 (17)	0.44131 (12)	0.0197 (3)
N2	0.5725 (2)	0.0199 (2)	0.39214 (14)	0.0317 (4)
C1	0.2618 (3)	0.7396 (2)	0.45537 (17)	0.0280 (5)
H1A	0.3475	0.8152	0.4583	0.042*
H1B	0.2020	0.7431	0.5179	0.042*
H1C	0.1925	0.7647	0.3991	0.042*
C2	0.4065 (2)	0.5148 (3)	0.51769 (14)	0.0226 (4)
H2	0.4191	0.5693	0.5790	0.027*
C3	0.4688 (2)	0.3685 (2)	0.50746 (15)	0.0231 (4)
H3	0.5244	0.3211	0.5609	0.028*
C4	0.4481 (2)	0.2915 (2)	0.41667 (15)	0.0204 (4)
C5	0.3665 (2)	0.3617 (2)	0.33903 (15)	0.0230 (4)
H5	0.3519	0.3096	0.2771	0.028*
C6	0.3075 (2)	0.5081 (2)	0.35368 (14)	0.0222 (4)
H6	0.2517	0.5579	0.3012	0.027*
C7	0.5161 (3)	0.1389 (2)	0.40273 (16)	0.0246 (4)
P1	0.32732 (6)	0.01238 (6)	0.69107 (4)	0.02273 (14)
F1	0.22985 (17)	0.16304 (16)	0.72363 (11)	0.0386 (4)
F2	0.48612 (19)	0.1071 (2)	0.70429 (16)	0.0594 (5)
F3	0.3350 (2)	−0.04134 (17)	0.80554 (10)	0.0471 (4)
F4	0.42360 (18)	−0.13840 (19)	0.65850 (12)	0.0446 (4)
F5	0.16725 (16)	−0.08286 (15)	0.67718 (10)	0.0326 (3)
F6	0.31409 (19)	0.06562 (16)	0.57645 (10)	0.0403 (4)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
N1	0.0209 (7)	0.0168 (7)	0.0213 (8)	−0.0018 (7)	0.0018 (6)	0.0005 (6)
N2	0.0355 (10)	0.0287 (9)	0.0310 (10)	0.0060 (8)	−0.0003 (8)	0.0012 (8)
C1	0.0374 (12)	0.0178 (9)	0.0289 (12)	0.0031 (8)	0.0009 (9)	−0.0037 (8)
C2	0.0259 (9)	0.0248 (9)	0.0171 (8)	−0.0056 (8)	−0.0023 (7)	−0.0018 (8)
C3	0.0238 (9)	0.0243 (10)	0.0213 (10)	−0.0036 (8)	−0.0035 (7)	0.0035 (8)
C4	0.0186 (8)	0.0195 (8)	0.0229 (9)	−0.0027 (7)	0.0013 (7)	0.0010 (7)
C5	0.0280 (10)	0.0218 (9)	0.0192 (9)	−0.0021 (7)	−0.0015 (7)	−0.0023 (7)
C6	0.0255 (9)	0.0215 (8)	0.0195 (9)	−0.0004 (8)	−0.0031 (7)	0.0018 (7)
C7	0.0257 (10)	0.0261 (10)	0.0220 (10)	0.0001 (8)	−0.0008 (8)	0.0017 (8)
P1	0.0237 (2)	0.0204 (2)	0.0241 (3)	0.00204 (19)	−0.00338 (19)	−0.00227 (19)
F1	0.0487 (8)	0.0299 (7)	0.0372 (8)	0.0158 (6)	−0.0114 (7)	−0.0105 (6)
F2	0.0318 (7)	0.0491 (9)	0.0972 (15)	−0.0113 (7)	−0.0132 (10)	−0.0124 (10)
F3	0.0709 (10)	0.0456 (8)	0.0246 (7)	0.0168 (8)	−0.0175 (7)	0.0008 (6)
F4	0.0438 (8)	0.0377 (8)	0.0524 (10)	0.0207 (7)	−0.0057 (7)	−0.0131 (7)
F5	0.0298 (6)	0.0325 (6)	0.0357 (7)	−0.0074 (6)	−0.0027 (6)	0.0051 (6)
F6	0.0550 (10)	0.0379 (7)	0.0281 (7)	−0.0040 (7)	0.0091 (7)	0.0076 (6)

Geometric parameters (Å, º) top

N1—C6	1.343 (2)	C4—C5	1.388 (3)
N1—C2	1.351 (2)	C4—C7	1.451 (3)
N1—C1	1.486 (2)	C5—C6	1.374 (3)
N2—C7	1.142 (3)	C5—H5	0.9500
C1—H1A	0.9800	C6—H6	0.9500
C1—H1B	0.9800	P1—F2	1.5918 (16)
C1—H1C	0.9800	P1—F4	1.5985 (14)
C2—C3	1.376 (3)	P1—F3	1.5992 (15)
C2—H2	0.9500	P1—F6	1.6026 (15)
C3—C4	1.394 (3)	P1—F1	1.6030 (14)
C3—H3	0.9500	P1—F5	1.6042 (14)

C6—N1—C2	121.37 (17)	C4—C5—H5	120.7
C6—N1—C1	119.67 (17)	N1—C6—C5	120.78 (18)
C2—N1—C1	118.95 (17)	N1—C6—H6	119.6
N1—C1—H1A	109.5	C5—C6—H6	119.6
N1—C1—H1B	109.5	N2—C7—C4	178.6 (2)
H1A—C1—H1B	109.5	F2—P1—F4	90.63 (9)
N1—C1—H1C	109.5	F2—P1—F3	90.45 (10)
H1A—C1—H1C	109.5	F4—P1—F3	90.20 (8)
H1B—C1—H1C	109.5	F2—P1—F6	91.08 (10)
N1—C2—C3	120.56 (19)	F4—P1—F6	90.54 (9)
N1—C2—H2	119.7	F3—P1—F6	178.30 (10)
C3—C2—H2	119.7	F2—P1—F1	89.70 (9)
C2—C3—C4	118.32 (19)	F4—P1—F1	179.67 (9)
C2—C3—H3	120.8	F3—P1—F1	89.81 (9)
C4—C3—H3	120.8	F6—P1—F1	89.45 (8)
C5—C4—C3	120.40 (19)	F2—P1—F5	179.72 (10)
C5—C4—C7	120.02 (19)	F4—P1—F5	89.37 (9)
C3—C4—C7	119.56 (19)	F3—P1—F5	89.83 (8)
C6—C5—C4	118.57 (19)	F6—P1—F5	88.64 (8)
C6—C5—H5	120.7	F1—P1—F5	90.30 (8)

C6—N1—C2—C3	0.1 (3)	C3—C4—C5—C6	0.2 (3)
C1—N1—C2—C3	179.82 (18)	C7—C4—C5—C6	−178.13 (17)
N1—C2—C3—C4	−0.1 (3)	C2—N1—C6—C5	0.1 (3)
C2—C3—C4—C5	0.0 (3)	C1—N1—C6—C5	−179.63 (18)
C2—C3—C4—C7	178.32 (18)	C4—C5—C6—N1	−0.2 (3)

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
C5—H5···F5ⁱ	0.95	2.37	3.247 (2)	153
C3—H3···F3ⁱⁱ	0.95	2.46	3.106 (2)	126
C1—H1C···F1ⁱⁱⁱ	0.98	2.51	3.208 (3)	128

Symmetry codes: (i) −x+1/2, −y, z−1/2; (ii) −x+1, y+1/2, −z+3/2; (iii) −x+1/2, −y+1, z−1/2.

Cation–anion interaction energies (kcal mol^-1) top

Compound 1		Compound 2		Compound 3
D—H···A	ΔE_int	D—H···A	ΔE_int	D—H···A	ΔE_int
C1—H1A···F4ⁱ	-19.0	C1—H1B···F4^iv	-16.6	C5—H5···F5^vi	-14.2
C1—H1B···F6ⁱⁱ	-15.9	C2—H2···F6^iv	-16.6	C3—H3···F3^vii	-15.3
C4—H4···F6	-15.7	C6—H6···F6^v	-17.8	C1—H1C···F1^viii	-16.7
C5—H5···F5ⁱⁱⁱ	-15.9

Symmetry codes: (i) -x + 1/2, y + 1/2, -z + 3/2; (ii) x + 1/2, -y + 3/2, z + 1/2; (iii) -x + 3/2, y + 1/2, -z + 3/2; (iv) -x + 1, y - 1/2, -z + 3/2; (v) x + 1, y, z; (vi) -x + 1/2, -y, z - 1/2; (vii) -x + 1, y + 1/2, -z + 3/2; (viii) -x + 1/2, -y + 1, z - 1/2.

Funding information

The support of NSF–MRI grant No. 1228232 for the purchase of the diffractometer and Tulane University for support of the Tulane Crystallography Laboratory are gratefully acknowledged. LVK acknowledges generous support from the Earl and Gertrude Vicknair Distinguished Professorship in Chemistry at Loyola University.

References

Bockman, T. M. & Kochi, J. K. (1989). J. Am. Chem. Soc. 111, 4669–4683. CSD CrossRef CAS Web of Science Google Scholar
Bockman, T. M. & Kochi, J. K. (1992). New J. Chem. 16, 39–49. CAS Google Scholar
Brandenburg, K. & Putz, H. (2012). DIAMOND, Crystal Impact GbR, Bonn, Germany. Google Scholar
Bruker (2015). APEX2 and SAINT. Bruker AXS Inc., Madison, Wisconsin, USA. Google Scholar
Chai, J.-D. & Head-Gordon, M. (2008). Phys. Chem. Chem. Phys. 10, 6615–6620. Web of Science CrossRef PubMed CAS Google Scholar
Chan, H., Chen, Y., Dai, M., Lu, C.-N., Wang, H.-F., Ren, Z.-G., Huang, Z.-J., Ni, C.-Y. & Lang, J.-P. (2012). ChemEngComm. 14, 466–473. Google Scholar
Glavcheva, Z., Umezawa, H., Okada, S. & Nakanishi, H. (2004). Mater. Lett. 58, 2466–2471. Web of Science CrossRef CAS Google Scholar
Grimme, S. (2006). J. Comput. Chem. 27, 1787–1799. Web of Science CrossRef PubMed CAS Google Scholar
Groom, C. R., Bruno, I. J., Lightfoot, M. P. & Ward, S. C. (2016). Acta Cryst. B72, 171–179. Web of Science CSD CrossRef IUCr Journals Google Scholar
Hardacre, C., Holbrey, J. D., Mullan, C. L., Nieuwenhuyzen, M., Reichert, W. M., Seddon, K. R. & Teat, S. J. (2008). New J. Chem. 32, 1953–1967. Web of Science CSD CrossRef CAS Google Scholar
Hardacre, C., Holbrey, J. D., Mullan, C. L., Nieuwenhuyzen, M., Youngs, T. G. A., Bowron, D. T. & Teat, S. J. (2010). Phys. Chem. Chem. Phys. 12, 1842–1853. Web of Science CSD CrossRef CAS PubMed Google Scholar
Johnson, E. R., Keinan, S., Mori-Sánchez, P., Contreras-García, J., Cohen, A. J. & Yang, W. (2010). J. Am. Chem. Soc. 132, 6498–6506. Web of Science CrossRef CAS PubMed Google Scholar
Jurečka, P., Černý, J., Hobza, P. & Salahub, D. (2007). J. Comput. Chem. 28, 555–569. Google Scholar
Kammer, M. N., Koplitz, L. V. & Mague, J. T. (2012a). Acta Cryst. E68, o2514. CSD CrossRef IUCr Journals Google Scholar
Kammer, M. N., Koplitz, L. V. & Mague, J. T. (2013). Acta Cryst. E69, o1281. CSD CrossRef IUCr Journals Google Scholar
Kammer, M. N., Mague, J. T. & Koplitz, L. V. (2012b). Acta Cryst. E68, o2409. CSD CrossRef IUCr Journals Google Scholar
Koplitz, L. V., Bay, K. D., DiGiovanni, N. & Mague, J. T. (2003). J. Chem. Cryst. 33, 391–402. CrossRef Google Scholar
Koplitz, L. V., Mague, J. T., Kammer, M. N., McCormick, C. A., Renfro, H. E. & Vumbaco, D. J. (2012). Acta Cryst. E68, o1653. CSD CrossRef IUCr Journals Google Scholar
Mague, J. T., Ivie, R. M., Hartsock, R. W., Koplitz, L. V. & Spulak, M. (2005). Acta Cryst. E61, o851–o853. Web of Science CSD CrossRef CAS IUCr Journals Google Scholar
Marenich, A. V., Cramer, C. J. & Truhlar, D. G. (2009). J. Phys. Chem. B, 113, 4538–4543. CrossRef Google Scholar
McCormick, C. A., Nguyen, V. D., Koplitz, L. V. & Mague, J. T. (2014). Acta Cryst. E70, o811. CSD CrossRef IUCr Journals Google Scholar
McCormick, C. A., Nguyen, V. D., Renfro, H. E., Koplitz, L. V. & Mague, J. T. (2013). Acta Cryst. E69, o981–o982. CSD CrossRef CAS IUCr Journals Google Scholar
Nguyen, V. D., McCormick, C. A., Koplitz, L. V. & Mague, J. T. (2014). Acta Cryst. E70, o756–o757. CSD CrossRef IUCr Journals Google Scholar
Nguyen, V. D., McCormick, C. A., Mague, J. T. & Koplitz, L. V. (2015a). Acta Cryst. E71, o852–o853. CrossRef IUCr Journals Google Scholar
Nguyen, V. D., McCormick, C. A., Pascal, R. A., Mague, J. T. & Koplitz, L. V. (2015b). Acta Cryst. E71, o854–o855. CrossRef IUCr Journals Google Scholar
Nguyen, V. D., McCormick, C. A., Vaccaro, F. A., Riley, K. E., Stephenson, C. J., Mague, J. T. & Koplitz, L. V. (2016). Polyhedron, 114, 428–434. CrossRef Google Scholar
Parsons, S., Flack, H. D. & Wagner, T. (2013). Acta Cryst. B69, 249–259. Web of Science CrossRef CAS IUCr Journals Google Scholar
Riley, K. E., Pitoňák, M., Jurečka, P. & Hobza, P. (2010). Chem. Rev. 110, 5023–5063. Web of Science CrossRef CAS PubMed Google Scholar
Riley, K. E., Tran, K. A., Lane, P., Murray, J. S. & Politzer, P. (2016). J. Comput. Sci. 17, 273–284. CrossRef Google Scholar
Riley, K. E., Vondrášek, J. & Hobza, P. (2007). Phys. Chem. Chem. Phys. 9, 5555–5560. CrossRef Google Scholar
Schröder, H., Hühnert, J. & Schwabe, T. (2017). J. Chem. Phys. 146, 044115. Google Scholar
Sedlak, R., Janowski, T., Pitoňák, M., Řezáč, J., Pulay, P. & Hobza, P. (2013). J. Chem. Theory Comput. 9, 3364–3374. CrossRef Google Scholar
Sheldrick, G. M. (2008a). Acta Cryst. A64, 112–122. Web of Science CrossRef CAS IUCr Journals Google Scholar
Sheldrick, G. M. (2008b). CELL_NOW, University of Göttingen, Göttingen, Germany. Google Scholar
Sheldrick, G. M. (2009). TWINABS, University of Göttingen, Göttingen, Germany. Google Scholar
Sheldrick, G. M. (2015a). Acta Cryst. A71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Sheldrick, G. M. (2015b). Acta Cryst. C71, 3–8. Web of Science CrossRef IUCr Journals Google Scholar
Shen, J., Zhang, C., Yu, T., An, L. & Fu, Y. (2014). Cryst. Growth Des. 14, 6337–6342. CrossRef Google Scholar
Vaccaro, F. A., Koplitz, L. V. & Mague, J. T. (2015). Acta Cryst. E71, o697–o698. Web of Science CSD CrossRef IUCr Journals Google Scholar
Wang, N., Wang, J.-G., Min, A.-J. & Fu, Y.-W. (2012). Acta Cryst. E68, m164. CrossRef IUCr Journals Google Scholar
Yu, T.-L., An, L., Zhang, L., Shen, J.-J., Fu, Y.-B. & Fu, Y.-L. (2014). Cryst. Growth Des. 14, 3875–3879. CrossRef Google Scholar
Zhu, D. & Kochi, J. K. (1999). Organometallics, 18, 161–172. Web of Science CSD CrossRef CAS Google Scholar

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Volume 74| Part 9| September 2018| Pages 1322-1329

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research communications\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

Crystal structures of the hexa­fluorido­phosphate salts of the isomeric 2-, 3- and 4-cyano-1-methyl­pyridinium cations and determination of solid-state inter­action energies

1. Chemical context

2. Structural commentary

3. Supra­molecular features

4. DFT studies

5. Database survey

6. Synthesis and crystallization

7. Refinement details

Supporting information

Funding information

References

research communications

Crystal structures of the hexafluoridophosphate salts of the isomeric 2-, 3- and 4-cyano-1-methylpyridinium cations and determination of solid-state interaction energies

3. Supramolecular features