Four tri­fluoro­methyl­nitro­benzene analogues

As part of a continuing series of studies into the conformational and solid-state packing modes of similar compounds, the authors have been investigating chemical isomers based on 3-nitrobenzotrifluoride (CAS No. 98–46-4, trifluoromethylnitrobenzene) where the nitro and trifluoromethyl (CF₃) groups are interchanged in relation to a third substituent on the benzene ring. These studies have the dual purpose of not only comparing structural behaviour in the individual components but also of attempting to prepare cocrystalline adducts with such compounds without the use of strong hydrogen-bonding associations, as achieved by Wheeler and co-workers (Hendi et al., 2001; Fomulu et al., 2002a,b). Both NO₂ and CF₃ groups are known to be weak hydrogen-bond acceptors from strong hydrogen-bond donors (Allen et al., 1997; Brammer et al., 2001), and in the absence of such donors, solid-state packing can only, if at all, be influenced by weaker C—H interactions. Furthermore, choice of the third substituent is based on the use of something flexible, not too bulky, and also lacking in strong hydrogen-bond donors. With this in mind, we prepared a series of analogues of 3-nitrobenzotrifluoride containing 4-substituted piperazines. Previous efforts had concentrated on the use of thiophenol derivatives, which had led to the structural characterization of 1-(4-chlorophenylthio)-2-nitro-4-trifluoromethylbenzene and 1-(4-chlorophenylthio)-4-nitro-2-trifluoromethylbenzene [Lynch & M^cClenaghan, 2003], whose similar conformations did not aid cocrystal formation. Instead it was suggested that the role of the C—H···O interactions in both individual structures promoted phase separation when attempts were made to cocrystallize the two. We report here the singl-crystal structures of 1-(4-carbethoxypiperazinyl)-4-nitro-2-trifluoromethylbenzene, (I), 1-(4-carbethoxypiperazinyl)-2-nitro-4-trifluoromethylbenzene, (II), 4-Nitro-1-(4-phenylpiperazinyl)-2-trifluoromethylbenzene, (III), and 2-Nitro-1-(4-phenylpiperazinyl)-4-trifluoromethylbenzene, (IV), and comment on their structural similarities/differences.

The difficulty in making structural comparisons between chemical isomers is that the structures of both are required. For the thiophenol containing 3-nitrobenzotrifluorides (trifluoromethylnitrobenzene), only one matching pair was characterized. Fortunately, for the 4-substituted piperazines, full structural analyses of two pairs were completed that allowed comparisons not only between (I) and (II), and (III) and (IV), but also between (I) and (III), and (II) and (IV), which share similar nitro (NO₂) and trifluoromethyl (CF₃) positions. The structures of (I)–(IV) are shown, perpendicular to the 3-nitrobenzotrifluoride ring, in Figs. 1–4, respectively, with interactions and contacts listed in Tables 1–4. Compounds (II) and (IV), where the CF₃ group is para to the piperazine ring, each have two unique molecules in their asymmetric units. For ease of comparison, these molecules are both shown as described above (in Figs. 2 and 4) and not as they would appear in the lattice. The numbering of both the N-phenyl and the piperazine rings has also been standardized to aid evaluation. An initial inspection of the molecules of (I)–(IV) shows that each adopts a linear rod-like conformation, as expected. Similarities arise in the rotation of the piperazine rings in (I), (IIA) and (IVB), and (IIB) and (IVA), which can be quantified via the C2—C1—N7—C8 torsion angles, as listed in Table 5. The twists in the N-phenyl rings can be represented by their dihedral angles with the 3-nitrobenzotrifluoride ring, viz. 46.4 (1) (III), and 59.6 (1) and 66.9 (1)° (IV). Both CF₃ groups in (II) are unequally disordered over two rotational occupancies, the major occupancies for both molecules being 85%. The minor occupancies are rotated 30 (3)° (molecule A) and 23 (6)° (molecule B) with respect to the major occupancy sites. The rotational positions of the comparative CF₃ groups in (II) and (IV) are similar; the C3—C4—C41—F43 torsion angles are listed in Table 5. Comparative CF₃ rotational positions in (I) and (III) can be defined by the C1—C2—C21—F22 torsion angle, listed in Table 5. Two torsion angles can be used to define the conformation of the carboxylate groups in (I) and (II), viz. C9—N10—C13—O14 and C13—O14—C15—C16, listed in Table 5, and these angles indicate very different rotational positions with respect to atom C9.

Packing diagrams for (I)–(IV) are shown in Figs. 5–8, respectively, while C—H···O/F close contacts are listed in Tables 1–4, respectively. The number of these contacts, per molecule, increases for the two carbethoxy-containing analogues as a result of the addition of the two carbethoxy O atoms. All O atoms, except for atom O22B in (II), across all molecules have at least one listed close contact, whereas only five of a possible 18 F atoms have a C—H···F association, none for either molecule in (II). However, in (III), atom F22 lies 3.010 (2) Å from atom N41 (x, 1/2 − y, −1/2 + z). The packing diagrams are typical for rod-shaped molecules, with three of the four being either monoclinic P2₁/c or P2₁/n. It is interesting to note the manner in which the molecules in (II) and (IV) associate asuni-directional pairs in close proximity to one another. The interplanar distance between the two benzene ring centroids in (II) is 3.95 (1) Å and the dihedral angle is 30.9 (4)°. Another feature is the 90° triclinic cell angle in (II). No additional symmetry could be found in this structure and the two molecules display no pseudo-symmetry relationship, thus the cell angle is real. It may eventuate that at 150 K the structure of (II) is near a phase change to a higher crystal system and that one angle had already moved to fit the higher cell, but this remains to be proved. Attempts to cocrystallize all possible combinations of compounds (I)–(IV), by dissolving equimolar amounts of two components in various solvents, with warming, and then allowing evaporation to dryness, led to the recrystallization in each case of the individual compounds. This was identified by distinct differences in crystal morphology as well as infrared analysis of each crystal type. In addition to differing C—H···O/F associations, the role of the paired formation in (II) and (IV) may be responsible for the inability of these compounds to form cocrystalline adducts without the presence of strong complimentary hydrogen-bonding groups. Unfortunately, the existence of pairing in (II) and (IV) adds a new consideration to our use of the 2-nitro-4-trifluoromethylbenzene analogue.