Cyclic hetero­tetra­meric and low-dimensional hydrogen-bonded polymeric structures in the morpholinium salts of ring-substituted benzoic acid analogues

The morpholinium (tetra­hydro-2H-1,4-oxazin-4-ium) cation has a proven history as a counter-ion in both inorganic and organic salt formation and particularly in metal complex stabilization, e.g. bis­(morpholin-4-ium) tetra­chloro­cuprate(II) (Willett et al., 1988), with rare examples in which it acts as an O-donor ligand species in complex formation, e.g. in dinuclear hexachloridobis(morpholin-1-ium-κO)dicopper(II) (Scott et al., 1988). In the current Cambridge Structural Database (CSD, Version?; Groom & Allen, 2014), there are 209 entries for the morpholinium cation. Of particular inter­est to us are the morpholinium carboxyl­ate salts, which number only ca 23, among which are those which have been used as models in studies of active pharmaceutical ingredients (APIs), e.g. the acetate (Kelley et al., 2013), the 4-amino­salicylate (André et al., 2009), the mono­hydrogen tartrate (a monohydrate; Liu, 2012) and the di­hydrogen citrate (also a monohydrate; Chen et al., 2003). A rare 1:1 salt adduct with 4-meth­oxy­benzoic acid (a monohydrate) is also known (Feng & Zhao, 2011). However, commonly, anhydrous organic morpholine salts are formed.

The crystal structures of only eight anhydrous morpholinium salts of the substituted benzoic acid analogues have been reported, e.g. with 4-nitro­benzoic acid (Chumakov et al., 2006), 5-nitro­salicylic acid (Smith et al., 2005), 4-amino­salicylic acid (André et al., 2009) and a series of isomeric chloro­nitro­benzoates (2,4-, 2,5-, 4,2-, 4,3- and 5,2-; Ishida et al., 2001a,b,c). In these, cation–anion N—H···O hydrogen-bonding inter­actions commonly generate either one-dimensional hydrogen-bonded ribbons (structure Type 1) or discrete cyclic hydrogen-bonded cage structures (Type 2), featuring primarily the R₄⁴(12) ring motif [for graph-set nomenclature, see Bernstein et al. (1995)] (Type 2a), such as is present in the structure of N-methyl­anilinium 3,5-di­nitro­benzoate (Smith et al., 1998), or the less common R₄²(8) ring motif (Type 2b) (Fig. 1), found in the analogous morpholinium phen­oxy­acetates (Smith & Lynch, 2015).

Within the Type 1 structures, the ribbons comprise either the more common –A–A–/–B–B– sequences (Type 1a) or the –A–B–/–B–A– sequences (Type 1b). The less common 1b subtype is found in the structure of morpholinium 2-chloro-4-nitro­benzoate (Ishida et al., 2001a) and in morpholinium (4-fluoro­phen­oxy)­acetate (Smith & Lynch, 2015), both of which have the A–B sequence generated by a crystallographic 2₁ screw operation.

The linear Type 1a chain structure is also found in the related anhydrous morpholinium salt of cinnamic acid (Smith, 2015) and two of the four morpholinium salts of phen­oxy­acetic acid analogues (Smith & Lynch, 2015). The fourth salt of this series, with (2,4-di­chloro­phen­oxy)­acetic acid, has the cyclic Type 2b structure. Of chemical inter­est is also the Type 2a structure of morpholinium morpholine-4-carboxyl­ate (Brown & Gray, 1982; Von Dreele et al., 1983), a salt often readily formed in attempted preparations of morpholine salts and also by the reaction of morpholine with dry ice.

One structure among the few known anhydrous morpholine salts of the associatively substituted benzoic acids which constitutes a variant of the above-described Type 1 and Type 2 sets is found in the 5-nitro­salicylate (Smith et al., 2005). In this structure, both the cations and anions lie, respectively, across and within crystallographic mirror planes, and the primary association is a variant of the Type 2a subset but with an R₄³(10) motif, involving three rather than four carboxyl­ate O atoms and giving an overall three-dimensional structure.

To examine the influence of inter­active substituent groups in the aromatic rings of, specifically, the benzoic acids upon secondary structure generation, the morpholinium salts with salicylic acid (SA), (3,5-di­nitro­salicylic acid (DNSA), 3,5-di­nitro­benzoic acid (DNBA) and 4-nitro­anthranilic acid (NAA), namely the title salts morpholinium 2-hy­droxy­benzoate, (I), morpholinium 2-carb­oxy-4,6-di­nitro­phenolate, (II), morpholinium 3,5-di­nitro­benzoate, (III), and morpholinium 2-amino-4-nitro­benzoate, (IV), were prepared and their crystal structures and hydrogen-bonding modes are reported herein. Morpholinium salicylate, (I), has a history of medical applications, as retarcyl or depasol, used as an analgesic, an anti­pyretic and an anti-inflammatory agent (O'Neil, 2001). With DNSA, a large number of structures of Lewis base salts have been reported of which ca 70% are phenolates rather than carboxyl­ates (Smith et al., 2007). However, with NAA, there is only one example of an anhydrous Lewis base salt, that with di­cyclo­hexyl­amine (Smith et al., 2004).

The title compounds, (I)–(IV), were prepared by the dropwise addition of morpholine at room temperature to solutions of salicylic acid (140 mg), 3,5-di­nitro­salicylic acid (230 mg), 3,5-di­nitro­benzoic acid (210 mg) or 4-nitro­anthranilic acid (170 mg), respectively, in ethanol (10 ml). Room-temperature evaporation of the solutions gave either fine yellow needles of (II), colourless plates of (III) or orange plates of (IV), from which specimens were cleaved for the X-ray analyses. For (I), the same preparative procedure was employed using salicylic acid, but the final oil which resulted after solvent evaporation was redissolved in ethanol, finally giving thin colourless plates from which a specimen was cleaved for the X-ray analysis.

Crystal data, data collection and structure refinement details are summarized in Table 1. The aminium, phenolic or carb­oxy­lic acid H atoms were located in difference Fourier analyses and allowed to refine with distance restraints of N—H = 0.90 (2) Å and U_iso(H) = 1.2U_eq(N) or O—H = 0.90 (2) Å and U_iso(H) = 1.5U_eq(O). The remaining H atoms were placed in calculated positions with aromatic C—H = 0.95 Å or methyl­ene C—H = 0.99 Å, and allowed to ride in the refinements, with U_iso(H) = 1.2U_eq(C). In the refinement of (I), the Flack parameter (Flack, 1983) for this achiral molecule [0.2 (14) for 1201 Friedel pairs] is meaningless.

The asymmetric units of (I)–(IV) comprise a morpholinium cation (B) and a salicylate anion (A) in (I) (Fig. 2), a 2-carb­oxy-4,6-di­nitro­phenolate anion (A) in (II) (Fig. 3), a 2,4-di­nitro­benzoate anion (A) in (III) (Fig. 4) and a 4-nitro­anthranilate anion (A) in (IV) (Fig. 5). In the structures of (I), (III) and (IV), two moderately strong morpholinium N1B—H···OA_carboxyl hydrogen-bonding inter­actions are present [N···O range = 2.6855 (17)–2.7756 (17) Å, both in (IV)] (Tables 2, 4 and 5).

With (II), which is a phenolate rather than a carboxyl­ate, the single N···O_{carboxyl­ate} assocation is weaker [2.912 (2) Å] than the N1B···H···(O:O¹) inter­action through a symmetric three-centre R₁²(6) chelate association with the phenolate (O2A) and nitro O31A acceptors [2.790 (2) and 2.806 (2) Å, respectively] (Table 3). This primary lateral associative mode is also found in the structures of the morpholinium salts of 2,4-di­nitro­phenol (Majerz et al., 1996) and picric acid (Vembu & Fronczek, 2009; Refat et al., 2010). The hydrogen-bonding extensions in (I)–(IV) result in different overall structures, while inter-ring π–π associations are present in two of these [(II) and (IV)].

With the morpholinium salt of salicylic acid, (I), the primary cation–anion pairs (Fig. 1) are linked through an N1B—H···O12Aⁱ hydrogen bond (Table 2), generating one-dimensional ribbon structures extending along b (Fig. 6). These ribbons have the Type 1b subset structure (the alternating parallel A,B,A,B/B,A,B,A anion–cation sequence in the chain) rather than the more common Type 1a subset. Other Type 1b chain polymers are found in morpholinium 2-chloro-4-nitro­benzoate (Ishida et al., 2001a) and in morpholinium (3,5-di­chloro­phen­oxy)­acetate (Smith & Lynch, 2015), which like (I) are propagated along crystallographic 2₁ screw axes. Present also in the structure of (I) are minor weak inter­chain C—H···O inter­actions with the morpholinium and phenolate O-atom acceptors. No π–π ring inter­actions are present in the structure.

In the salicylate anion, the common short intra­molecular cyclic S6 carboxyl O—H···O_phenolate hydrogen bond is present, with the carboxyl­ate group rotated only slightly out of the benzene plane [torsion angle C2A—C1A—C11A—O12A = -172.2 (2)°].

In the structure of the morpholinium salt of DNSA, (II), since the primary strong N—H···O inter­action involves the phenolate and nitro O atoms of the DNSA anion rather than the second carboxyl O atom (Table 3), a variant of the Type 1b (A,B,A,B) chain structure is found, extending parallel to the a direction (Fig. 7). Present also in the crystal structure are π–π inter­actions, with benzene ring-centroid separations Cg···Cgⁱⁱⁱ of 3.5516 (9) Å and Cg···Cg^iv of 3.7700 (9) Å [symmetry codes: (iii) -x + 3/2, - y + 1/2, -z + 1/2; (iv) -x + 3/2, y, z]. There are also minor C—H···O inter­actions to morpholinium and carboxyl O-atom acceptors (Table 3).

The DNSA anion, like other DNSA phenolate anions having the anti-related carboxyl group, has the short intra­molecular S(6) carboxyl O—H···O_phenolate hydrogen bond and is close to coplanar with the benzene ring [torsion angle C2A—C1A—C11A—O12A = -177.39 (15)°], as is one of the nitro groups [C4A—C5A—N5A—O52A = 178.95 (16)°]. However, the hydrogen-bond associated N3A nitro group is significantly rotated [C2A—C3A—N3A—O32A = -160.26 (14)°].

In the DNBA salt, (III), the N1B—H···O12Aⁱ hydrogen bond generates a centrosymmetric hetero­tetra­meric Type 2a ring structure [graph set R₄⁴(12)] (Fig. 8; see Table 4 for symmetry code). This cyclic system is similar to that found in the structures of morpholinium 4-amino­salicylate (André et al., 2009) and in four of the five morpholinium salts with the isomeric chloro-nitro-substituted benzoic acids (2-chloro-5-nitro-, 4-chloro-2-nitro-, 4-chloro-3-nitro- and 5-chloro-2-nitro; Ishida et al., 2001b, 2001c). It is also found in the previously mentioned morpholinium morpholine-4-carboxyl­ate salt (Brown & Gray, 1982; Von Dreele et al., 1983). In (IV) [Should this be (III)?], weak C—H···O hydrogen bonds are also found, involving O_morpholine acceptors. No π–π inter­actions are present.

As is quite common with the DNBA cation, the carboxyl­ate group and the two nitro-substituent groups are essentially coplanar with the benzene ring [torsion angles: C2A—C1A—C11A—O12A = -171.3 (3)°; C2A—C3A—N3A—O32A = 179.3 (3)°; C4A—C5A—N5A—O52A = -178.0 (3)°].

With the structure of the NAA salt, (IV), the primary N1B—H···O12A hydrogen-bonded unit is linked by the second N1B—H···O11Aⁱ hydrogen-bonding inter­action (Table 5) into a centrosymmetric cyclic Type 2a hetero­tetra­mer substructure [graph set R₄⁴(12)]. The amino group of the anion expands the structure along [010] through an N1B—H···O11Aⁱⁱ hydrogen bond into a two-layered ribbon which lies parallel to (001) (Fig. 9; see Table 5 for symmetry code). A weak π–π inter­action Cg···Cgⁱⁱⁱ of 3.7340 (9) Å is found [symmetry code (iii) as above for salt (II)?], as well as a weak cation C—H···O_nitro hydrogen bond (Table 5). The second H atom of the amino group participates in an intra­molecular S(6) N—H···O hydrogen-bonding motif with a carboxyl O12A-atom acceptor, with the carboxyl group rotated slightly out of the benzene plane [torsion angle C6A—C1A—C11A—O12A = -161.96 (13)°], while the nitro group is close to coplanar with the ring [torsion angle C3A—C4A—N4A—O42A = -178.96 (13)°]. Unlike the hetero­tetra­mer in (III) which is essentially planar, in (IV) it is quite convoluted.

The structures of the morpholinium salts of the associatively substituted benzoic acid analogues reported here provide examples of both the common Type 1 and Type 2 hydrogen-bonded structures found among the anhydrous morpholinium salts, but the presence of associative substitutent groups influences the structure types, giving variants.