1. Chemical context

N-(2-Meth­oxy­phen­yl)piperazine (2-MeOPP) has been used as a building block in the synthesis of both 5-HT_1A receptor ligands (Orjales et al., 1995) and dopamine D₂ and D₃ ligands (Hackling et al., 2003), and also as a building block for the synthesis of derivatives exhibiting anti­depressant-like activity (Waszkielewicz et al., 2015). We have recently reported the structures of a range of salts derived from 2-MeOPP (Harish Chinthal et al., 2020a) and here we report the syntheses and structures of six 1-haloaroyl-4-(2-meth­oxy­phen­yl)piperazines, (I)–(VI). The work reported here represents a continuation of an earlier study on the isomeric N-(4-meth­oxy­phen­yl)piperazine (4-MeOPP) (Kiran Kumar et al., 2020) and a range of salts and N-aroyl derivatives derived from 4-MeOPP (Kiran Kumar, Yathirajan, Foro et al., 2019; Kiran Kumar, Yathirajan, Sagar et al., 2019; Kiran Kumar et al., 2020). Compounds (I)–(VI) were prepared using carbodi­imide-mediated reactions between N-(2-meth­oxy­phen­yl)piperazine and a halogen-substituted benzoic acid.

2. Structural commentary

Despite differing only in the identity of their halogen substituents, no two of compounds (I)–(IV) are isomorphous (Figs. 1–6). The chloro and bromo compounds (II) and (III) both crystallize in space group Pca2₁, but with Z′ values of 2 and 4, respectively; the unit-cell repeat vectors b and c for these two compounds are quite similar, but the a repeat vector for (II) is roughly twice that for (III). Compound (V) also crystallizes with Z′ = 2, but in space group P2₁2₁2₁.

Figure 1 The mol­ecular structure of compound (I), showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level.

Figure 2 The structures of the four independent mol­ecules in the selected asymmetric unit of compound (II), viewed approximately along [001], showing the atom-labelling scheme, and the approximate spacial relationships between the mol­ecules. Displacement ellipsoids are drawn at the 30% probability level and, for the sake of clarity, the H atoms have been omitted.

Figure 3 The structures of the two independent mol­ecules in the selected asymmetric unit of compound (III), viewed approximately along [001], showing the atom-labelling scheme, the disorder in one of the mol­ecules and the approximate glide relationship between the two mol­ecules. The major disorder component is drawn using full lines and the minor disorder component is drawn using broken lines: displacement ellipsoids are drawn at the 30% probability level and, for the sake of clarity, a few of the atom labels have been omitted.

Figure 4 The mol­ecular structure of compound (IV), showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level.

Figure 5 The structures of the two independent mol­ecules in the selected asymmetric unit of compound (V), showing the atom-labelling scheme and the approximate inversion symmetry relating the two mol­ecules. Displacement ellipsoids are drawn at the 30% probability level.

Figure 6 The mol­ecular structure of compound (VI), showing the atom-labelling scheme. Displacement ellipsoids are drawn at the 30% probability level.

In none of the compounds reported here do the mol­ecules exhibit any inter­nal symmetry and hence they are conformationally chiral. The space groups for compounds (II), (III), (IV) and (VI) confirm the presence in the crystal of equal numbers of the two conformational enanti­omers. For each of (II), (III) and (V), having Z′ > 1, there is considerable flexibility available for the choice of the asymmetric unit: in each case, the asymmetric unit was selected such that the independent mol­ecules in it were linked by C—H⋯O hydrogen bonds (Table 1).

Table 1 Hydrogen bonds (Å, °) Cg1–Cg7 represent the centroids of the rings (C41–C46), (C441–C446), (C241–C246), (C241–C246), (C141–C146), (C211–C216) and (C111–C116), respectively. Compound D—H⋯A D—H H⋯A D⋯A D—H⋯A (I) C15—H15⋯O17i 0.93 2.48 3.409 (4) 173   C13—H13⋯Cg1ii 0.93 2.82 3.559 (4) 151             (II) C15—H15B⋯O417iii 0.97 2.39 3.314 (9) 160   C35—H365B⋯O217 0.97 2.41 3.333 (9) 159   C115—H115⋯O217 0.93 2.60 3.522 (9) 174   C215—H215⋯O117iv 0.93 2.56 3.482 (8) 170   C315—H315⋯O417 0.93 2.56 3.486 (9) 177   C415—H415⋯O317v 0.93 2.52 3.428 (8) 165   C213—H213⋯Cg2vi 0.93 2.71 3.604 (8) 161   C313—H313⋯Cg3vii 0.93 2.79 3.633 (8) 151             (III) C15—H15B⋯O217 0.97 2.56 3.483 (10) 159   C25—H25B⋯O115iii 0.97 2.55 3.483 (11) 160   C213—H213⋯O217viii 0.93 2.54 3.425 (10) 158   C312—H312⋯N14viii 0.93 2.59 3.45 (9) 154   C115—H115⋯Cg4ix 0.93 2.65 3.549 (9) 162   C315—H315⋯Cg5x 0.93 2.74 3.59 (10) 151             (IV) C3—H3A⋯O17xi 0.97 2.50 3.422 (4) 159             (V) C112—H112⋯O242 0.93 2.55 3.388 (9) 150   C116—H116⋯O217xii 0.93 2.41 3.301 (10) 159   C212—H212⋯O142 0.93 2.55 3.363 (9) 147   C216—H216⋯O117xiii 0.93 2.49 3.407 (11) 169   C115—H115⋯Cg6xii 0.93 2.67 3.505 (9) 149   C215—H215⋯Cg7xiii 0.93 2.81 3.566 (9) 140             (VI) C15—H15⋯O17i 0.93 2.58 3.510 (3) 177 Symmetry codes: (i) −1 + x, y, z; (ii) − + x,  − y, −z; (iii) x, −1 + y, z; (iv) − + x, 1 − y, z; (v)  + x, 2 − y, z; (vi) 1 − x, 1 − y, − + z; (vii) 1 − x, 1 − y,  + z; (viii)  + x, 1 − y, z; (ix) 1 − x, 1 − y, − + z; (x)  − x, y,  + z; (xi) 1 − x,  + y,  − z; (xii) 1 − x, − + y,  − z; (xiii) −x,  + y,  − z.

For compound (I), which crystallizes in space group P2₁2₁2₁ with Z′ = 1, it was not possible to establish the absolute configuration of the mol­ecules in the crystal selected for data collection (see Section 6). In compound (V), the two independent mol­ecules in the selected asymmetric unit have opposite conformations and they are related by an approximate, but non-crystallographic, inversion close to (0.25, 0.60, 0.25) (cf. Fig. 5), and so (V) may be regarded as a kryptoracemate (Fábián & Brock, 2010). Pseudosymmetry is also apparent in compounds (II) and (III). In (III), where Z′ = 2, mol­ecule 1 containing atom Br14 and the major disorder component of mol­ecule 2 containing atom Br24 are related by an approximate, but non-crystallographic b-glide plane at x = ca 0.62 (cf. Fig. III). The arrangement of the mol­ecules in compound (II) is slightly more complex: mol­ecules 1 and 3, containing atoms Cl14 and Cl34, respectively, are related by an approximate, but non-crystallographic, 2₁ screw axis along (0.56, y, 0.68), as also are mol­ecules 2 and 4, containing atoms Cl24 and Cl44 (cf. Fig. 2). In addition, mol­ecules 1 and 2 are approximately related by the translation (x − 0.25, y + 0.06, z), while mol­ecules 3 and 4 are approximately related by the translation (x + 0.25, y + 0.06, z). Compounds (II), (III) and (V) all exhibit a measure of inversion twinning (Section 6, below) and it seems likely that this is underpinned by the pseudosymmetry in these structures.

All of the piperazine rings in compounds (I)–(VI) adopt chair type conformations, with values of the ring-puckering angle θ (Cremer & Pople, 1975) close to zero, as calculated for the atom sequences (N1,C2,C3,N4,C5,C6) in (I), (IV) and (VI), or (Nx1,Cx2,Cx3,Nx4,Cx5,Cx6) where x = 1 or 2 in (III) and (V) and x = 1, 2, 3 or 4 in (II). For an ideal chair conformation, the value of θ is zero (Boeyens, 1978). The substituents at the N atoms all occupy equatorial sites.

In each of (I)–(IV), the meth­oxy C atom is close to coplanar with the adjacent aryl ring, with displacements from the plane of the ring ranging from 0.024 (7) Å in mol­ecule 4 of (II) to 0.130 (3) Å in (I): for (V) and (VI) the displacements are rather larger, up to 0.447 (1) Å in mol­ecule 2 of (V). However, in every mol­ecule the two exocyclic C—C—O angles differ by ca 10°, as typically found in planar, or near-planar, alk­oxy­arenes (Seip & Seip, 1973; Ferguson et al., 1996).

3. Supra­molecular features

In assessing the inter­molecular inter­actions, we have discounted hydrogen bonds having D—H⋯A angles that are significantly less than 140°, as the inter­action energies associated with such contacts are likely to be very low, so that these cannot be regarded as structurally significant (Wood et al., 2009). We have also discounted short contacts involving the H atoms of the methyl groups, as such groups are likely to be undergoing rapid rotation about the adjacent C—O bonds (Riddell & Rogerson, 1996, 1997). The C—H⋯π(arene) contacts have been included only where the H⋯Cg distances are less than 2.85 Å. It should perhaps be conceded here that these are somewhat arbitrary judgments, made with the primary aim of avoiding over-inter­pretation of the longer contacts and over-complication of the crystal-structure descriptions. It is convenient to consider first the supra­molecular assembly in compounds (I), (IV) and (VI) where Z′ = 1 and the aggregation is one-dimensional, followed by (III) and (V) where Z′ = 2 and the aggregation is two-dimensional, and finally (II) where Z′ = 4 and the aggregation is three-dimensional.

The assembly in compounds (I), (IV) and (VI) is very simple. In (I), a single C—H⋯O hydrogen bond (Table 1) links mol­ecules which are related by translation to form a C(6) (Etter, 1990; Etter et al., 1990; Bernstein et al., 1995) chain, which is weakly reinforced by a C—H⋯π(arene) hydrogen bond to form a chain of rings running along (x, 0.25, 0) (Fig. 7). Simple C(6) chains are also formed in compounds (IV) and (VI), although these involve different donors. The chain in (IV) is built from mol­ecules related by the 2₁ screw axis along (0.5, y, 0.25) (Fig. 8), while that in (VI) contains mol­ecules related by translation along [100] (Fig. 9), analogous to that in (I). In none of (I), (IV) and (VI) are there any direction-specific inter­actions between adjacent chains so that, in each case, the assembly is one-dimensional.

Figure 7 Part of the crystal structure of compound (I), showing the formation of a hydrogen-bonded chain of rings running parallel to [100]. Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms not involved in the motif shown have been omitted.

Figure 8 Part of the crystal structure of compound (IV), showing the formation of a hydrogen-bonded chain running parallel to [010]. Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms bonded to the C atoms which are not involved in the motif shown have been omitted.

Figure 9 Part of the crystal structure of compound (VI), showing the formation of a hydrogen-bonded chain running parallel to [100]. Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms which are not involved in the motif shown have been omitted.

Because of the very low occupancy of the minor disorder component in (III), it is necessary to consider only the inter­actions involving the major disorder component, where a combination of C—H⋯O and C—H⋯π(arene) hydrogen bonds links the mol­ecules into a sheet lying parallel to (100) (Fig. 10). The assembly in (V) is also two-dimensional, but it is rather more complex than that in (III); however, it is possible to analyse the sheet formation in (V) in terms of three simpler sub-structures (Ferguson et al., 1998a,b; Gregson et al., 2000). The first of these sub-structures, which can be regarded as the basic building block in the structure, consists of the two mol­ecules within the selected asymmetric unit (Fig. 5), which are linked by two C—H⋯O hydrogen bonds to form a cyclic dimeric unit containing an R₂²(22) motif, and dimers of this type are linked to form two types of chains of rings. One of these chains contains dimers which are related by the 2₁ screw axis along (0.5, y, 0.25) (Fig. 11) and the other is built from dimers related by the 2₁ screw axis along (0, y, 0.25) (Fig. 12). Within these two chains, the hydrogen bonds are directed in opposite directions (Table 1), and the combination of the two chains generates a complex sheet lying parallel to (001). There are no direction-specific inter­actions between adjacent sheets in either (III) or (V).

Figure 10 Part of the crystal structure of compound (III), showing the formation of a hydrogen-bonded sheet lying parallel to (100). Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the minor disorder component and the H atoms bonded to the C atoms which are not involved in the motif shown have been omitted.

Figure 11 Part of the crystal structure of compound (V), showing the formation of a hydrogen-bonded chain of rings running along (1/2, y, 1/4). Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms which are not involved in the motif shown have been omitted.

Figure 12 Part of the crystal structure of compound (V), showing the formation of a hydrogen-bonded chain of rings running along (0, y, 1/4). Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms which are not involved in the motif shown have been omitted.

No fewer than six independent C—H⋯O hydrogen bonds, three of them within the selected asymmetric unit, link the mol­ecules of compound (II) into a complex sheet lying parallel to (001) (Fig. 13). In addition, two independent C—H⋯π(arene) hydrogen bonds link mol­ecules related by the 2₁ screw axis along (0.5, 0.5, z) to generate a chain running parallel to the [001] direction (Fig. 14) and chains of this type link the (001) sheets to form a continuous three-dimensional network.

Figure 13 Part of the crystal structure of compound (II), showing the formation of a hydrogen-bonded sheet lying parallel to (001). Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms bonded to those C atoms which are not involved in the motif shown have been omitted.

Figure 14 Part of the crystal structure of compound (II), showing the formation of a hydrogen-bonded chain running parallel to [001]. Hydrogen bonds are drawn as dashed lines and, for the sake of clarity, the H atoms bonded to those C atoms which are not involved in the motif shown have been omitted.

4. Database survey

Here we briefly compare the structures of compounds (I)–(VI) with those of some analogous compounds. In the structure of 1-(2-fluoro­benzo­yl)-4-(4-meth­oxy­phen­yl)piperazine (VII), which is isomeric with compound (VI) reported here, the mol­ecules are linked by two C—H⋯O hydrogen bonds to form a chain of centrosymmetric rings containing two distinct types of R₂²(10) ring (Kiran Kumar, Yathirajan, Sagar et al., 2019). The 2-chloro, 2-bromo and 2-iodo analogues of (VII), [compounds (VIII)–(X)], are isomorphous in space group Pbca, all with Z′ = 1 (Kiran Kumar, Yathirajan, Sagar et al., 2019), whereas no two of compounds (I)–(IV) reported here are isomorphous. In each of (VIII)–(X), the mol­ecules are linked into sheets by two C—H⋯π(arene) hydrogen bonds: the assembly in (VIII)–(X) thus differs markedly from that in the isomeric compounds (I)–(IV). By contrast with the assembly in (VIII)–(X), there are no significant hydrogen bonds in the structure of the unsubstituted analogue 1-benzoyl-4-(4-meth­oxy­phen­yl)piperazine (XI) (Kiran Kumar, Yathirajan, Sagar et al., 2019), just as there are none in the structure of 1-(3,5-di­nitro­benzo­yl)-4-(2-meth­oxy­phen­yl)piperazine (XII) (Harish Chinthal et al., 2020b). Finally, we note that structures have been reported recently for 1-(2-iodo­benzo­yl)-4-(pyrimidin-2-yl)piperazine (Mahesha, Yathirajan et al., 2019) and for three 1-(1,3-benzodioxol-5-yl)methyl-4-(halobenzo­yl)piperazines (Mahesha, Sagar et al., 2019).

5. Synthesis and crystallization

All reagents were commercially available and all were used as received. For the synthesis of compounds (I)–(VI), 1-(3-di­methyl­amino­prop­yl)-3-ethyl­carbodi­imide (134 mg, 0.7 mmol), 1-hy­droxy­benzotriazole (68 mg, 0.5 mmol) and tri­ethyl­amine (0.5 ml, 1.5 mmol) were added to a solution of the appropriately substituted benzoic acid (0.52 mmol) in methanol (10 ml), thus 4-fluoro­benzoic acid (73 mg) for (I), 4-chloro­benzoic acid (82 mg) for (II), 4-bromo­benzoic acid (103 mg) for (III), 4-iodo­benzoic acid (129 mg) for (IV), 3-iodo­benzoic acid (129 mg) for (V) and 2-fluoro­benzoic acid (73 mg) for (VI). Each mixture was stirred at 323 K for a few minutes and then set aside for two days at room temperature. A solution of N-(2-meth­oxy­phen­yl)piperazine (100 mg, 0.52 mmol) in N,N-di­methyl­formamide (5 ml) was then added to each of the mixtures prepared as above, followed by stirring that was continued overnight at room temperature. When the reactions were confirmed to be complete using thin-layer chromatography, each mixture was then quenched with water (10 ml) and extracted with ethyl acetate (20 ml). Each organic fraction was separated and washed successively with an aqueous hydro­chloric acid solution (1 M), a saturated solution of sodium hydrogencarbonate and then with brine. The organic phases were dried over anhydrous sodium sulfate and the solvent was then removed under reduced pressure. The resulting solid products were then crystallized from acetone–ethyl acetate (1:1, v/v) for (I) or methanol–ethyl acetate (1:1. v/v) solvent mixtures for (II)–(VI): m.p. (I) 375–377 K, (II) 383–387 K, (III) 377–379 K, (IV) 378–381 K, (V) 379–381 K and (VI) 341–345 K. Crystals suitable for single-crystal X-ray diffraction were grown by slow evaporation, at ambient temperature and in the presence of air, of solutions in ethyl acetate.

6. Refinement

Crystal data, data collection and structure refinement details are summarized in Table 2. One bad outlier reflection (2,0,2) was omitted from the final refinement for compound (IV), and two bad outlier reflections, (1,5,18) and (1,18,15), were omitted from the final refinement for compound (V). All H atoms, apart from those in the minor disorder component of compound (III), were located in difference maps and subsequently treated as riding atoms in geometrically idealized positions, with C—H distances 0.93 Å (aromatic), 0.96 Å (CH₃) and 0.97 Å (CH₂), and with U_iso(H) = kU_eq(C), where k = 1.5 for the methyl groups, which were allowed to rotate but not to tilt, and 1.2 for all other H atoms. For the minor disorder component in (III), the bonded distances and the 1,3 non-bonded distances were restrained to be the same as the corresponding distances in the major disorder component, subject to s.u. values of 0.01 and 0.02 Å, respectively. In addition, the anisotropic displacement parameters for pairs of atoms occupying essentially the same physical space were constrained to be identical. Subject to these conditions, the refined disorder occupancies were 0.939 (4) and 0.061 (4). In the absence of significant resonant scattering, it was not possible to determine the absolute configuration of the mol­ecules of (I) in the crystal selected for data collection. The value of the Flack x parameter [Flack (1983), x = −0.2 (8), calculated (Parsons et al., 2013) using 612 quotients of the type [(I⁺) − (I⁻)]/[(I⁺) + (I⁻)], means that the absolute structure is indeterminate (Flack & Bernardinelli, 2000), although this has no chemical significance. For each of (II), (III) and (V), the Flack x parameter indicated the occurrence of inversion twinning (Flack & Bernardinelli, 2000), thus: for (II), x = 0.22 (8) calculated using 1164 quotients; for (III), x = 0.300 (6) calculated using 1164 quotients; and for (V), x = 0.456 (12) calculated using 1728 quotients. The structure of (I) contains two void spaces, each of volume 65 ų and centred close to (0, 0.25, 0) and (0, 0.75, 0.5); however, examination of the refined structure using SQUEEZE (Spek, 2015) showed that these voids contained negligible electron density. There are four small voids in the structure of (II), each of volume ca 32 ų, and all too small to accommodate even a water mol­ecule (Hofmann, 2002).

Table 2 Experimental details   (I) (II) (III) Crystal data Chemical formula C18H19FN2O2 C18H19ClN2O2 C18H19BrN2O2 Mr 314.35 330.80 375.26 Crystal system, space group Orthorhombic, P212121 Orthorhombic, Pca21 Orthorhombic, Pca21 Temperature (K) 296 296 293 a, b, c (Å) 7.3286 (6), 11.3388 (7), 20.304 (1) 29.769 (1), 11.3173 (4), 20.4028 (8) 15.0779 (7), 11.2868 (6), 20.5297 (9) α, β, γ (°) 90, 90, 90 90, 90, 90 90, 90, 90 V (Å3) 1687.21 (19) 6873.8 (4) 3493.8 (3) Z 4 16 8 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 0.09 0.23 2.36 Crystal size (mm) 0.44 × 0.14 × 0.14 0.48 × 0.38 × 0.28 0.50 × 0.48 × 0.24   Data collection Diffractometer Oxford Diffraction Xcalibur CCD Oxford Diffraction Xcalibur CCD Oxford Diffraction Xcalibur CCD Absorption correction Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Tmin, Tmax 0.938, 0.988 0.874, 0.937 0.294, 0.567 No. of measured, independent and observed [I > 2σ(I)] reflections 6377, 3377, 1918 17985, 8328, 4822 13342, 5910, 3300 Rint 0.036 0.030 0.031 (sin θ/λ)max (Å−1) 0.628 0.606 0.606   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.044, 0.088, 0.92 0.055, 0.143, 0.95 0.051, 0.130, 0.93 No. of reflections 3377 8328 5910 No. of parameters 209 833 445 No. of restraints 0 1 21 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 0.12, −0.14 0.52, −0.19 0.85, −0.49 Absolute structure – Flack x determined using 1164 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Flack x determined using 1109 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) Absolute structure parameter – 0.22 (6) 0.300 (6)   (IV) (V) (VI) Crystal data Chemical formula C18H19IN2O2 C18H19IN2O2 C18H19FN2O2 Mr 422.25 422.25 314.35 Crystal system, space group Monoclinic, P21/c Orthorhombic, P212121 Monoclinic, P21/n Temperature (K) 296 296 296 a, b, c (Å) 10.9626 (5), 11.3258 (6), 14.8234 (7) 7.4528 (4), 17.1306 (9), 27.903 (1) 7.451 (1), 11.199 (3), 19.138 (5) α, β, γ (°) 90, 104.520 (5), 90 90, 90, 90 90, 99.59 (2), 90 V (Å3) 1781.69 (16) 3562.4 (3) 1574.6 (6) Z 4 8 4 Radiation type Mo Kα Mo Kα Mo Kα μ (mm−1) 1.81 1.81 0.10 Crystal size (mm) 0.42 × 0.40 × 0.28 0.36 × 0.22 × 0.18 0.48 × 0.48 × 0.24   Data collection Diffractometer Oxford Diffraction Xcalibur CCD Oxford Diffraction Xcalibur CCD Oxford Diffraction Xcalibur CCD Absorption correction Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Multi-scan (CrysAlis RED; Oxford Diffraction, 2009) Tmin, Tmax 0.423, 0.603 0.542, 0.722 0.898, 0.955 No. of measured, independent and observed [I > 2σ(I)] reflections 7512, 3816, 2690 13774, 7653, 5048 6456, 3467, 2081 Rint 0.015 0.025 0.025 (sin θ/λ)max (Å−1) 0.651 0.650 0.659   Refinement R[F2 > 2σ(F2)], wR(F2), S 0.035, 0.092, 1.05 0.048, 0.116, 1.04 0.049, 0.128, 1.02 No. of reflections 3816 7653 3467 No. of parameters 208 417 208 No. of restraints 0 0 0 H-atom treatment H-atom parameters constrained H-atom parameters constrained H-atom parameters constrained Δρmax, Δρmin (e Å−3) 0.43, −0.91 1.12, −0.69 0.17, −0.17 Absolute structure – Flack x determined using 1728 quotients [(I+)−(I−)]/[(I+)+(I−)] (Parsons et al., 2013) – Absolute structure parameter – 0.456 (12) – Computer programs: CrysAlis CCD and CrysAlis RED (Oxford Diffraction, 2009), SHELXT (Sheldrick, 2015a), SHELXL2014 (Sheldrick, 2015b) and PLATON (Spek, 2020).