(E)-4-[2-(3,4,5-Trimeth­oxy­phenyl)ethen­yl]nitro­benzene and its `bridge-flipped' analogues

Collas, A.; Blockhuys, F.

doi:10.1107/S0108270111030952

organic compounds

STRUCTURAL
CHEMISTRY

ISSN: 2053-2296

Volume 67| Part 9| September 2011| Pages o364-o369

doi:10.1107/S0108270111030952

(E)-4-[2-(3,4,5-Trimethoxyphenyl)ethenyl]nitrobenzene and its `bridge-flipped' analogues

Alain Collas ^a and Frank Blockhuys ^a ^*

^aDepartment of Chemistry, University of Antwerp, Universiteitsplein 1, B-2610 Antwerp, Belgium
^*Correspondence e-mail: frank.blockhuys@ua.ac.be

(Received 5 July 2011; accepted 1 August 2011; online 17 August 2011)

The solid-state structures of three push–pull acceptor-π-donor (A-π-D) systems differing only in the nature of the π-spacer have been determined. (E)-1-Nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene, C₁₇H₁₇NO₅, (I), and its `bridge-flipped' imine analogues, (E)-3,4,5-trimethoxy-N-(4-nitrobenzylidene)aniline, C₁₆H₁₆N₂O₅, (II), and (E)-4-nitro-N-(3,4,5-trimethoxybenzylidene)aniline, C₁₆H₁₆N₂O₅, (III), display different kinds of supramolecular networks, viz. corrugated planes, a herringbone pattern and a layered structure, respectively, all with zero overall dipole moments. Only (III) crystallizes in a noncentrosymmetric space group (P2₁2₁2₁) and is, therefore, a potential material for second-harmonic generation (SHG).

Comment

For several years now, the liquid-crystal-forming properties of N-benzylideneaniline (BA) and its derivatives have been studied in great detail (Kitamura et al., 1986 ; Ajeetha & Pisipati, 2006 ; Fakruddin et al., 2009 ); their rod-like shape is the basis of a number of unique properties which lead to calamitic liquid crystals that may find application in customizable electro-optical switches. The aromatic moieties in BAs have been described as the main recognition points of the mesogens used in the organization of the liquid-crystalline superstructure (Neuvonen et al., 2006 ). Extended alkyl or alkoxy chains are substituted onto these aromatic fragments to introduce the necessary flexibility into the molecular structure, and this flexibility is further enhanced by the imine spacers present in the BA. It is the subtle equilibrium between the rigid rod-like structure and the presence of flexible groups that determines the physical properties of the liquid-crystalline phase. Since the solid-state structures of these materials can not be studied in the liquid-crystalline phase, the extended side chains must be replaced by shorter ones, such as methoxy groups, in order to investigate the intermolecular interactions involving the mesogen.

Push–pull acceptor-π-donor (A-π-D) systems are of particular interest in this context because of their superior charge-transfer-related nonlinear electrical and optical properties, such as the electro-optic effect (EO) and second-harmonic generation (SHG). Unfortunately, the large molecular dipoles associated with such push–pull systems usually lead to centrosymmetric organization of the molecules in the crystal structure, annihilating bulk second-order optical effects such as SHG. It has been suggested that whether or not an asymmetric dipolar BA crystallizes centrosymmetrically is largely dependent on the molecular planarity, which may be directly

related to the molecular rigidity mentioned above; more planar molecules have a greater possibility of crystallizing in a noncentrosymmetric space group (Zhang, 2002

). To verify Zhang's correlation, a search of the Cambridge Structural Database (CSD, Version 5.32, with update of February 2011; Allen, 2002

) was conducted for all stilbenes and BAs having no ortho substituents. Indeed, since ortho substituents can easily give rise to steric hindrance or intramolecular hydrogen bonding, a correlation involving the planarity of the systems would be biased. Erroneous, cocrystal, polymeric, ionic, powder and organometallic structures, and symmetric structures with Z′ = 0.5, were also excluded. On the other hand, heterocyclic rings with the heteroatom in the 3-, 4- or 5-position were allowed. For the stilbenes, only E configurations [τ(C1—C7—C8—C9) = 180±15°] were considered. The distribution of torsion angles in the resulting structures is given in Fig. 1

. As can be seen from these polar histograms, the stilbenes are all quasiplanar (Fig. 1

a). The majority of the BAs, on the other hand, display conformations with torsion angles within the ±45° range (Fig. 1

b). 64 of the 169 stilbenes and 44 of the 178 BAs found belong to noncentrosymmetric space groups. 53 stilbenes and 81 BAs are donor–acceptor (DA) systems. 17 and 19 of these, respectively, belong to noncentrosymmetric space groups. As can be seen from Fig. 1

(c) though, the torsion angles of these 19 BAs (or 23 structures, with the addition of four polymorphs) are quite well distributed over the entire ±45° range. Based on these results, the suggested correlation seems unlikely.

It is interesting to note that usually just one of the structures of the three possible stilbene/BA derivatives (i.e. with —CH=CH—, —CH=N— or —N=CH— as spacer) is available, so that a direct comparison of the effect of the spacer on the supramolecular structure is impossible. In order to make just such a comparison, the stilbene (E)-1-nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene, (I), and its two `bridge-flipped' (Ojala et al., 2009 ) imine derivatives, (E)-3,4,5-trimethoxy-N-(4-nitrobenzylidene)aniline, (II), and (E)-4-nitro-N-(3,4,5-trimethoxybenzylidene)aniline, (III) (Fig. 2), were prepared and structurally characterized.

Compounds (I) and (II) crystallize in the centrosymmetric space group P2₁/c, while (III) crystallizes in the chiral space group P2₁2₁2₁. Compound (I) is quasiplanar, while the imine derivatives (II) and (III) display the typical 40° twist around the C—N bond which is also found in the calculated gas-phase structures, as evidenced by the values of τ(C1—N2) for (II) and τ(N2—C9) for (III) in Table 1.

The quasiplanar molecules of (I) (Fig. 3a) form pairs, in which the two molecules are held together by dipolar forces and π^δ+–π^δ− interactions, with CgA⋯CgBⁱ = 3.936 (4) Å [CgA and CgB are the centroids of the nitro-substituted (A) and trimethoxy-substituted (B) benzene rings, respectively; symmetry code: (i) −x, −y + 1, −z], α = 2.20 (14)° and γ = 30.07°, where α is defined as the dihedral angle between the least-squares (LS) planes through rings A and B, and γ as the angle between the CgA⋯CgB vector and the normal to the LS plane through ring B (Fig. 3b). This two-by-two arrangement leads to layers in which the distance between the molecules is less than 4.2 Å – the photochemical criterion (Schmidt, 1971 ) – and, as a consequence, this crystal structure should be photosensitive, but this was not observed during the manipulation of the compound. These nonpolar pairs are further stabilized on both sides by weak hydrogen bonds involving the O atom of the nitro group (Fig. 3d and entry 1 in Table 2) and an O atom of a methoxy group (Fig. 3d and entry 2 in Table 2), which gives a structure formed of planes two molecules thick. These planes are then fused together by reciprocal OCH₃⋯π contacts (Fig. 3c and entry 3 in Table 2). The overall result is a supramolecular structure of corrugated planes (Fig. 3a).

The crystal structure of (II) is also based on pairs of molecules in which their large individual dipoles are cancelled. As a result, π–π stacking can be easily recognized [CgA⋯CgA^v = 3.993 (1) Å, α = 0.0° and γ = 25.79°; symmetry code: (v) −x + 1, −y + 2, −z + 1] (Fig. 4). These dimers are further stabilized by a mutual weak hydrogen bond involving atom H6 and an O atom of the nitro group (Fig. 4b and entry 1 in Table 3). Ribbons are then generated by a weak C—H⋯O hydrogen bond between the methoxy groups in the 4- and 5-positions (Fig. 4b and entry 2 in Table 3). Simultaneously, atom H41B engages in a C—H⋯π contact with the π-system of the methoxy-substituted aniline fragment (entry 3 in Table 3, not shown in Fig. 4). Perpendicular to these ribbons, another OCH₃⋯π contact is initiated by the methoxy group in the 3-position, which is made possible by the twist of the aniline ring (entry 4 in Table 3, not shown in Fig. 4). In the third direction, a C—H⋯O interaction (entry 5 in Table 3) and an OCH₃⋯π interaction (entry 6 in Table 3) stabilize the structure further (not shown in Fig. 4). Both the imine N atom and the relatively acidic H8 atom remain unused in this structure.

Compound (III), which crystallizes in the chiral space group P2₁2₁2₁, does not form these antiparallel assemblies. It is remarkable that a hydrogen bond involving imine atom N2 as acceptor generates a ribbon of molecules in the bc plane (Fig. 5b and entry 1 in Table 4). These ribbons are further expanded into a plane of molecules by an additional hydrogen bond (Fig. 5b and entry 2 in Table 4). In the direction perpendicular to the plane, the [100] direction, atom O2 of the nitro group contacts the π-systems of the aniline rings in the planes above (Fig. 5a and entry 3 in Table 4) and below the molecule (entry 4 in Table 4, not shown in Fig. 5). Thus, the layered structure (Fig. 5c) is stabilized in all three directions, but as a result of this particular stacking, the molecular dipoles add up to zero, in keeping with the observed space group symmetry.

It may be clear from the above that (I) and (II) aggregate as dimers, cancelling out the net dipole in each case and constructing centrosymmetric corrugated layered and herringbone networks, respectively. π–π stacking involving the nitro-substituted A rings occurs in the solid-state structures of (I) and (II) as a consequence of the contribution of dipolar forces (see Table 1 for the calculated dipole moments). The methoxy groups are engaged in almost equal numbers of OCH₃⋯π and C—H⋯O interactions. Surprisingly, compound (III) possesses the largest dipole but displays a noncentrosymmetric network based on weak hydrogen bonds involving the imine N atom. The chiral network is essential for displaying nonlinear responses based on the second-order nonlinear electrical susceptibility (χ⁽²⁾).

Figure 1
Polar histograms illustrating the distribution of (a) torsion angles τ(C2—C1—C7—C8) in stilbenes, (b) torsion angles τ(C2—C1—N2—C8) in BAs and (c) torsion angles of donor–acceptor BAs in noncentrosymmetric space groups; see Comment for details.

Figure 2
The molecular structures of (I)

, (II)

and (III)

, showing the atom-numbering scheme. In each case, the nitro-substituted ring is labelled A. Displacement ellipsoids are drawn at the 50% probability level. H atoms are represented by spheres of arbitrary radii and bear the same number as the C atom to which they are attached.

Figure 3
(a) The corrugated planes in the structure of (I)

, held together by (b) π–π, (c) OCH₃⋯π and (d) C—H⋯O interactions (all interactions are shown as dashed lines). Symmetry codes are as in Table 2.

Figure 4
(a) The herringbone pattern in the structure of (II)

, viewed along the a axis and (b) the various other intermolecular contacts (dashed lines). Symmetry codes are as in Table 3.

Figure 5
(a) The NO⋯π contacts, (b) the interactions within the layers and (c) the layered structure of (III)

, viewed along b (all interactions are shown as dashed lines). Symmetry codes are as in Table 4.

Experimental

All reagents and solvents were obtained from ACROS and used as received. All NMR spectra were recorded on a Bruker Avance II spectrometer at frequencies of 400 MHz for ¹H and 100 MHz for ¹³C in CDCl₃ with tetramethylsilane (TMS) as internal standard; chemical shifts δ are given in p.p.m. and coupling constants J in Hz. Melting points were obtained with an open capillary electrothermal melting-point apparatus and are uncorrected.

(E)-1-Nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene, (I), was prepared by adding LiOH (0.7 g, 0.03 mol) to a stirred solution of (4-nitrobenzyl)triphenylphosphonium chloride (13.1 g, 0.03 mol) and 3,4,5-trimethoxybenzaldehyde (6.0 g, 0.03 mol) in propan-2-ol (110 ml). The resulting suspension was refluxed for 18 h. After cooling to room temperature, water (100 ml) was added, and since no precipitate was formed the solution was extracted with diethyl ether (3 × 50 ml). The organic layer was separated off and evaporated to dryness. Isomerization of the crude product in p-xylene (50 ml) with a catalytic amount of I₂ yielded 2.4 g (0.007 mol, 23%) of long yellow needles of (I). Characterization: m.p. 466 K; ¹H NMR: δ 3.89 (s, 3H,4-OCH₃), 3.93 (s, 6H, 3-OCH₃ and 5-OCH₃), 6.78 (s, 2H, H2 and H6), 7.03 (d, ³J = 16.1, 1H, H7), 7.19 (d, ³J = 16.1, 1H, H8), 7.61 (d, ³J = 8.2, 2H, H11 and H13), 8.20 (d, ³J = 8.2, 2H, H10 and H14); ¹³C NMR: δ 56.22 (3-OCH₃ and 5-OCH₃), 60.98 (4-OCH₃), 104.32 (C2 and C6), 124.15 (C10 and C14), 125.69 (C8), 126.74 (C7), 131.86 (C11 and C13), 133.31 (C1), 139.13 (C4), 143.82 (C12), 146.73 (C9), 153.56 (C3 and C5). Crystals used in the diffraction experiment were grown by slow cooling of an ethyl acetate–hexane (1:1 v/v) solution.

(E)-3,4,5-Trimethoxy-N-(4-nitrobenzylidene)aniline, (II), was prepared by dissolving 3,4,5-trimethoxyaniline (1.8 g, 0.01 mol) and 4-nitrobenzaldehyde (1.5 g, 0.01 mol) in ethanol (100 ml) and stirring the solution overnight. The orange precipitate which formed was filtered off, yielding 3.0 g (9.5 mmol, 95%) of (II). Characterization: m.p. 430 K; ¹H NMR: δ 3.88 (s, 3H, 4-OCH₃), 3.92 (s, 6H, 3-OCH₃ and 5-OCH₃), 6.56 (s, 2H, H2 and H6), 8.07 (d, ³J = 8.8, 2H, H10 and H14), 8.32 (d, ³J = 8.8, 2H, H11 and H13), 8.57 (s, 1H, H8); ¹³C NMR: δ 56.23 (3-OCH₃ and 5-OCH₃), 61.02 (4-OCH₃), 98.60 (C2 and C6), 124.03 (C11 and C13), 129.31 (C10 and C14), 137.58 (C4), 141.53 (C9), 146.63 (C1), 149.31 (C12), 153.86 (C3 and C5), 156.40 (C8). Crystals used in the diffraction experiment were grown by slow evaporation from a CH₂Cl₂ solution.

(E)-4-Nitro-N-(3,4,5-trimethoxybenzylidene)aniline, (III), was prepared by refluxing 3,4,5-trimethoxybenzaldehyde (3.0 g, 0.015 mol) and 4-nitroaniline (2.1 g, 0.015 mol) in methanol (100 ml) for 3 h. The resulting yellow precipitate was collected by filtration and recrystallized from acetonitrile, yielding 3.5 g (11 mmol, 75%) of (III). Crystals from this batch were used in the crystallographic experiment. Characterization: m.p. 428 K; ¹H NMR: δ 3.94 (s, 3H, 4-OCH₃), 3.95 (s, 6H, 3-OCH₃ and 5-OCH₃), 7.18 (s, 2H, H2 and H6), 7.23 (dd, ³J = 8.9, ⁴J = 1.9, 2H, H10 and H14), 8.25 (dd, ³J = 8.9, ⁴J = 1.9, 2H, H11 and H13), 8.32 (s, 1H, H7); ¹³C NMR: δ 56.33 (3-OCH₃ and 5-OCH₃), 61.03 (4-OCH₃), 106.44 (C2 and C6), 121.29 (C10 and C14), 125.04 (C11 and C13), 130.81 (C1), 142.01 (C4), 145.45 (C12), 153.65 (C3 and C5), 157.87 (C9), 162.08 (C7).

Compound (I)

Crystal data

C₁₇H₁₇NO₅
M_r = 315.32
Monoclinic, P 2₁ /c
a = 10.459 (2) Å
b = 12.88 (1) Å
c = 14.021 (4) Å
β = 124.069 (15)°
V = 1564.6 (13) Å³
Z = 4
Mo Kα radiation
μ = 0.10 mm⁻¹
T = 293 K
0.42 × 0.39 × 0.39 mm

Data collection

Enraf–Nonius CAD-4 diffractometer
5901 measured reflections
2867 independent reflections
1500 reflections with I > 2σ(I)
R_int = 0.043
3 standard reflections every 60 min intensity decay: none

Refinement

R[F² > 2σ(F²)] = 0.045
wR(F²) = 0.135
S = 1.00
2867 reflections
211 parameters
H-atom parameters constrained
Δρ_max = 0.35 e Å⁻³
Δρ_min = −0.14 e Å⁻³

Compound (II)

Crystal data

C₁₆H₁₆N₂O₅
M_r = 316.31
Monoclinic, P 2₁ /c
a = 7.512 (2) Å
b = 7.895 (1) Å
c = 26.441 (6) Å
β = 104.667 (19)°
V = 1517.0 (6) Å³
Z = 4
Mo Kα radiation
μ = 0.10 mm⁻¹
T = 293 K
0.3 × 0.3 × 0.3 mm

Data collection

Enraf–Nonius CAD-4 diffractometer
5826 measured reflections
2803 independent reflections
2023 reflections with I > 2σ(I)
R_int = 0.052
3 standard reflections every 60 min intensity decay: 4%

Refinement

R[F² > 2σ(F²)] = 0.036
wR(F²) = 0.104
S = 1.05
2803 reflections
211 parameters
H-atom parameters constrained
Δρ_max = 0.14 e Å⁻³
Δρ_min = −0.18 e Å⁻³

Compound (III)

Crystal data

C₁₆H₁₆N₂O₅
M_r = 316.31
Orthorhombic, P 2₁ 2₁ 2₁
a = 7.215 (3) Å
b = 14.429 (2) Å
c = 14.595 (5) Å
V = 1519.4 (8) Å³
Z = 4
Mo Kα radiation
μ = 0.10 mm⁻¹
T = 293 K
0.4 × 0.4 × 0.3 mm

Data collection

Enraf–Nonius CAD-4 diffractometer
4683 measured reflections
1618 independent reflections
1358 reflections with I > 2σ(I)
R_int = 0.057
3 standard reflections every 60 min intensity decay: 10%

Refinement

R[F² > 2σ(F²)] = 0.052
wR(F²) = 0.141
S = 1.07
1618 reflections
212 parameters
H-atom parameters constrained
Δρ_max = 0.30 e Å⁻³
Δρ_min = −0.21 e Å⁻³

Table 1
Selected geometric data for (I), (II) and (III); calculated (DFT) and experimental (XRD) torsion angles in degrees (°), and calculated dipole moments μ in Debye

Compound	Parameter	XRD	DFT	μ
(I)	C2—C1—C7—C8	−11.0 (5)	176.2
	C1—C7—C8—C9	178.7 (3)	0.3	5.48
	C7—C8—C9—C10	−172.1 (3)	4.2
(II)	C2—C1—N2—C8	−38.4 (2)	31.6
	C1—N2—C8—C9	179.4 (1)	177.4	4.59
	N2—C8—C9—C10	−11.5 (2)	1.4
(III)	C2—C1—C7—N2	4.1 (4)	1.4
	C1—C7—N2—C9	177.8 (2)	176.4	6.15
	C7—N2—C9—C10	−39.5 (4)	42.5

Table 2
Weak hydrogen bonds in (I) (Å, °)

Entry	D	H	A	H⋯A	D⋯A	D—H⋯A
1	C14	H14	O2ⁱⁱ	2.69	3.526 (4)	151
2	C7	H7	O4ⁱⁱⁱ	2.57	3.447 (3)	158
3	C31	H31B	CgB^iv	2.83	3.718 (5)	154
Symmetry codes: (ii) x, −y + $[{1\over 2}]$ , z − $[{1\over 2}]$ ; (iii) x, −y + $[{3\over 2}]$ , z + $[{1\over 2}]$ ; (iv) x + 1, −y + 1, −z.

Table 3
Weak hydrogen bonds in (II) (Å, °)

Entry	D	H	A	H⋯A	D⋯A	D—H⋯A
1	C6	H6	O2^v	2.54	3.423 (2)	160
2	C41	H41C	O5^vi	2.50	3.450 (3)	168
3	C41	H41B	CgB^vii	2.96	3.626 (3)	128
4	C31	H31A	CgB^viii	2.78	3.463 (3)	129
5	C31	H31B	O1^ix	2.71	3.542 (3)	145
6	C51	H51B	CgA^x	2.94	3.631 (3)	130
Symmetry codes: (v) −x + 1, −y + 2, −z + 1; (vi) −x + 3, y + $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (vii) −x + 3, y − $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (viii) −x + 2, y + $[{1\over 2}]$ , −z + $[{3\over 2}]$ ; (ix) x + 1, −y + $[{3\over 2}]$ , z + $[{1\over 2}]$ ; (x) x + 1, y − 1, z.

Table 4
Short contacts in (III) (Å, °)

Entry	D	X	A	X⋯A	D⋯A	D—X⋯A
1	C41	H41B	N2^xi	2.66	3.537 (4)	153
2	C6	H6	O1^xii	2.58	3.450 (4)	156
3	N1	O2	CgB^xiii	3.610 (4)	3.587 (4)	79.1 (2)
4	N1	O2	CgB^xiv	3.912 (4)	4.578 (4)	115.7 (2)
Symmetry codes: (xi) −x, $[{1\over 2}]$ + y, $[{1\over 2}]$ − z; (xii) −x, $[{1\over 2}]$ + y, − $[{1\over 2}]$ − z; (xiii) − $[{1\over 2}]$ + x, $[{1\over 2}]$ − y, −z; (xiv) $[{1\over 2}]$ + x, $[{1\over 2}]$ − y, −z.

The molecular structures of isolated molecules of (I), (II) and (III) were optimized at the DFT/B3LYP/6-31G* level of theory using the GAUSSIAN09 program package (Frisch et al., 2009 ); the functional and basis set were used as they are implemented in the program. Frequency calculations were performed to ascertain that the resulting structures are minima on the potential-energy surface (PES). Molecular dipoles of the four molecules in the unit cell of (III) were calculated in their solid-state geometries at the same level of theory. The resulting vectors were then transformed from the Cartesian to the unit-cell coordinate system. The polar histograms were generated using the VISTA program in the CSD suite.

All H atoms were treated as riding using SHELXL97 (Sheldrick, 2008 ) defaults at 293 (1) K, with C—H = 0.93 Å and U_iso(H) = 1.2U_eq(C) for aromatic H atoms, and C—H = 0.96 Å and U_iso(H) = 1.5U_eq(C) for methyl H atoms. The displacement parameters of atoms C7 and C8 in (I) seem to suggest disorder typical of ethenylic spacers in stilbene-type systems (see Vande Velde et al., 2011 ), but attempts to refine a disordered model did not lead to satisfactory results. However, since only a small fraction of misoriented fragments is present, the quality of the nondisordered model was found to be sufficient, even though this leads to slightly larger displacement ellipsoids for the mentioned atoms. For (III), Friedel pairs were collected independently but were merged (MERG 3 command in SHELXL97) for the final refinement. In the absence of a heavy atom [Z > 14 (Si)], and with the use of Mo radiation, anomalous scattering could not be used to determine an absolute structure and thus it was chosen arbitrarily.

For all compounds, data collection: CAD-4 EXPRESS (Enraf–Nonius, 1994 ); cell refinement: CAD-4 EXPRESS; data reduction: XCAD4 (Harms & Wocadlo, 1996 ); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: ORTEP-3 (Farrugia, 1997 ) and Mercury (Macrae et al., 2008 ); software used to prepare material for publication: WinGX (Farrugia, 1999 ) and PLATON (Spek, 2009 ).

Supporting information

Crystal structure: contains datablocks I, II, III, global. DOI: 10.1107/S0108270111030952/fa3256sup1.cif

Structure factors: contains datablock I. DOI: 10.1107/S0108270111030952/fa3256Isup2.hkl

Structure factors: contains datablock II. DOI: 10.1107/S0108270111030952/fa3256IIsup3.hkl

Structure factors: contains datablock III. DOI: 10.1107/S0108270111030952/fa3256IIIsup4.hkl

Comment top

For several years now, the liquid-crystal forming properties of N-benzylideneaniline (BA) and its derivatives have been studied in great detail (Kitamura et al., 1986; Ajeetha & Pisipati, 2006; Fakruddin et al., 2009): their rod-like shape is the basis of a number of unique properties which lead to calamitic liquid crystals that may find application in customizable electro-optical switches. The aromatic moieties in BAs have been described as the main recognition points of the mesogens, used in the organization of the liquid-crystalline superstructure (Neuvonen et al., 2006). Extended alkyl or alkoxy chains are substituted ontothese aromatic fragments to introduce the necessary flexibility into the molecular structure, and this flexibility is further enhanced by the imine spacers present in the BA. It is the subtle equilibrium between the rigid rod-like structure and the presence of flexible groups that determines the physical properties of the liquid-crystalline phase. Since the solid-state structures of these materials can not be studied in the liquid-crystalline phase, the extended side chains must be replaced by shorter ones, such as methoxy groups, in order to investigate the intermolecular interactions involving the mesogen.

Push–pull acceptor-π-donor (A-π-D) systems are of particular interest in this context because of their superior charge-transfer related nonlinear electrical and optical properties, such as the electro-optic effect (EO) and second-harmonic generation (SHG). Unfortunately, the large molecular dipoles associated with such push–pull systems usually lead to centrosymmetric organization of the molecules in the crystal structure, annihilating bulk second-order optical effects such as SHG. It has been suggested that whether or not an asymmetrical dipolar BA crystallizes centrosymmetrically is largely dependent on the molecular planarity, which may be directly related to the molecular rigidity mentioned above: more planar molecules have a greater possibility of crystallizing in a noncentrosymmetric space group (Zhang, 2002). To verify Zhang's correlation, a search of the Cambridge Structural Database (CSD, Version?; Allen, 2002) was conducted for all stilbenes and BAs without ortho substituents. Indeed, since ortho substituents can easily give rise to steric hindrance or intramolecular hydrogen bonding, a correlation involving the planarity of the systems would be biased. Erroneous, co-crystal, polymeric, ionic, powder and organometallic structures, and symmetric structures with Z' = 0.5, were also excluded. On the other hand, heterocyclic rings with the heteroatom in the 3-, 4- or 5-position were allowed. For the stilbenes, only E configurations [τ(C1—C7—C8—C9) = 180±15°] were considered. The distribution of torsion angles in the resulting structures is given in Fig. 1. As can be seen from these polar histograms, the stilbenes are all quasi-planar (Fig. 1a). The majority of the BAs, on the other hand, display conformations with torsion angles within the ±45° range (Fig. 1b). 64 of the 169 stilbenes and 44 of the 178 BAs found belong to noncentrosymmetric space groups. 53 stilbenes and 81 BAs are donor–acceptor (DA) systems. 17 and 19 of these, respectively, belong to noncentrosymmetric space groups. As can be seen from Fig. 1(c), though, the torsion angles of these 19 BAs (or 23 structures, with the addition of four polymorphs) are quite well distributed over the entire ±45° range. Based on these results, the suggested correlation seems unlikely.

It is interesting to note that usually just one of the structures of the three possible stilbene/BA derivatives (i.e. with —CH═CH—, —CH═ N— or —N═CH— as spacer) is available, so that a direct comparison of the effect of the spacer on the supramolecular structure is impossible. In order to make just such a comparison, the stilbene (E)-1-nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene, (I), and its two `bridge-flipped' (Ojala et al., 2009) imine derivatives, (E)-3,4,5-trimethoxy-N-(4-nitrobenzylidene)aniline, (II), and (E)-4-nitro-N-(3,4,5-trimethoxybenzylidene)aniline, (III) (Fig. 2), were prepared and structurally characterized.

The quasiplanar molecules of (I) (Fig. 3a) form pairs, in which the two molecules are held together by dipolar forces and π^δ⁺···π^δ^- interactions, with CgA···CgBⁱ = 3.936 (4) Å [CgA and CgB are the centroids of rings A and B, respectively; symmetry code: (i) -x, 1 - y, -z], α = 2.20 (14)° and γ = 30.07°, where α is defined as the dihedral angle between the least-squares (LS) planes through rings A and B, and γ as the angle between the CgA···CgB vector and the normal to the LS plane through ring B (Fig. 3b). This two-by-two arrangement leads to layers in which the distance between the molecules is less than 4.2 Å - the photochemical criterion (Schmidt, 1971) - and, as a consequence, this crystal structure should be photosensitive, but this was not observed during the manipulation of the compound. These nonpolar pairs are further stabilized on both sides by weak hydrogen bonds involving the O atom of the nitro group (Fig. 3d and Table 2, entry 1) and an O atom of a methoxy group (Fig. 3d and Table 2, entry 2), which gives a structure formed of planes two molecules thick. These planes are then fused together by reciprocal OCH₃···π contacts (Fig. 3c and Table 2, entry 3). The overall result is a supramolecular structure of corrugated planes (Fig. 3a).

The crystal structure of (II) is also based on pairs of molecules in which their large individual dipoles are cancelled. As a result, π–π stacking can be easily recognized [CgA···CgA^v = 3.993 (1) Å, α = 0.0° and γ = 25.79°; symmetry code: (v) 1 - x, 2 - y, 1 - z] (Fig. 4). These dimers are stabilized further by a mutual weak hydrogen bond involving atom H6 and an O atom of the nitro group (Fig. 4b and Table 3, entry 1). Ribbons are then generated by a weak C—H···O hydrogen bond between the methoxy groups in the 4- and 5-positions (Fig. 4b and Table 3, entry 2). Simultaneously, atom H41B engages in a C—H···π contact with the π-system of the methoxy-substituted aniline fragment (Table 3, entry 3, not shown in Fig. 4). Perpendicular to these ribbons, another OCH₃···π contact is initiated by the methoxy group in the 3-position, which is made possible by the twist of the aniline ring (Table 3, entry 4, not shown in Fig. 4). In the third direction, a C—H···O interaction (Table 3, entry 5) and an OCH₃···π interaction (Table 3, entry 6) stabilize the structure further (not shown in Fig. 4). Both the imine N atom and the relatively acidic atom H8 remain unused in this structure.

Compound (III), which crystallizes in the chiral space group P2₁2₁2₁, does not form these antiparallel assemblies. It is remarkable that a hydrogen bond involving imine atom N2 as acceptor generates a ribbon of molecules in the bc plane (Fig. 5b and Table 4, entry 1). These ribbons are further expanded into a plane of molecules by an additional hydrogen bond (Fig. 5b and Table 4, entry 2). In the direction perpendicular to the plane, the [100] direction, atom O2 of the nitro group contacts the π-systems of the aniline rings in the planes above (Fig. 5a and Table 4, entry 3) and below the molecule (Table 4, entry 4, not shown in Fig. 5). Thus, the layered structure (Fig. 5c) is stabilized in all three directions, but as a result of this particular stacking the molecular dipoles add up to zero, in keeping with the observed space group symmetry.

It may be clear from the above that (I) and (II) aggregate as dimers, cancelling out the net dipole in each case and constructing centrosymmetric corrugated layered and herringbone networks, respectively. π–π stacking involving the nitro-substituted A rings occurs in the solid-state structures of (I) and (II) as a consequence of the contribution of dipolar forces (see Table 1 for the calculated dipole moments). The methoxy groups are engaged in almost equal numbers of OCH₃···π and C—H···O interactions. Surprisingly, compound (III) possesses the largest dipole but displays a noncentrosymmetric network based on weak hydrogen bonds involving the imine N atom. The chiral network is essential for displaying nonlinear responses based on the second-order nonlinear electrical susceptibility (χ⁽²⁾).

Related literature top

For related literature, see: Ajeetha & Pisipati (2006); Allen (2002); Fakruddin et al. (2009); Frisch (2009); Kitamura et al. (1986); Neuvonen et al. (2006); Ojala et al. (2009); Schmidt (1971); Sheldrick (2008); Vande Velde, Collas, De Borger & Blockhuys (2011); Zhang (2002).

Experimental top

The molecular structures of isolated molecules of (I), (II) and (III) were optimized at the DFT/B3LYP/6-31G* level of theory using the GAUSSIAN09 program package (Frisch et al., 2009); the functional and basis set were used as they are implemented in the program. Frequency calculations were performed to ascertain that the resulting structures are minima on the potential-energy surface (PES). Molecular dipoles of the four molecules in the unit cell of (III) were calculated in their solid-state geometries at the same level of theory. The resulting vectors were then transformed from the Cartesian to the unit-cell coordinate system. The polar histograms were generated using the VISTA program in the CSD suite.

(E)-1-Nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene, (I), was prepared by adding LiOH (0.7 g, 0.03 mol) to a stirred solution of (4-nitrobenzyl)triphenylphosphonium chloride (13.1 g, 0.03 mol) and 3,4,5-trimethoxybenzaldehyde (6.0 g, 0.03 mol) in propan-2-ol (110 ml). The resulting suspension was refluxed for 18 h. After cooling to room temperature, water (100 ml) was added, and since no precipitate was formed the solution was extracted with diethyl ether (3 × 50 ml). The organic layer was separated off and evaporated to dryness. Isomerization of the crude product in p-xylene (50 ml) with a catalytic amount of I₂ yielded 2.4 g (0.007 mol, 23%) of long yellow needles of (I). Characterisation: m.p. 466 K; δ¹H 3.89 (s, 3H, 4-OCH₃), 3.93 (s, 6H, 3-OCH₃ and 5-OCH₃), 6.78 (s, 2H, H2 and H6), 7.03 (d, ³J = 16.1, 1H, H7), 7.19 (d, ³J = 16.1, 1H, H8), 7.61 (d, ³J = 8.2, 2H, H11 and H13), 8.20 (d, ³J = 8.2, 2H, H10 and H14); δ¹³C 56.22 (3-OCH₃ and 5-OCH₃), 60.98 (4-OCH₃), 104.32 (C2 and C6), 124.15 (C10 and C14), 125.69 (C8), 126.74 (C7), 131.86 (C11 and C13), 133.31 (C1), 139.13 (C4), 143.82 (C12), 146.73 (C9), 153.56 (C3 and C5). Crystals used in the diffraction experiment were grown by slow cooling of an ethyl acetate/hexane (Solvent ratio?) solution.

(E)-3,4,5-Trimethoxy-N-(4-nitrobenzylidene)aniline, (II), was prepared by dissolving 3,4,5-trimethoxyaniline (1.8 g, 0.01 mol) and 4-nitrobenzaldehyde (1.5 g, 0.01 mol) in ethanol (Volume?) and stirring the solution overnight. The orange precipitate which formed was filtered off, yielding 3.0 g (9.5 mmol, 95%) of (II). Characterisation: m.p. 430 K; δ¹H 3.88 (s, 3H, 4-OCH₃), 3.92 (s, 6H, 3-OCH₃ and 5-OCH₃), 6.56 (s, 2H, H2 and H6), 8.07 (d, ³J = 8.8, 2H, H10 and H14), 8.32 (d, ³J = 8.8, 2H, H11 and H13), 8.57 (s, 1H, H8); δ¹³C 56.23 (3-OCH₃ and 5-OCH₃), 61.02 (4-OCH₃), 98.60 (C2 and C6), 124.03 (C11 and C13), 129.31 (C10 and C14), 137.58 (C4), 141.53 (C9), 146.63 (C1), 149.31 (C12), 153.86 (C3 and C5), 156.40 (C8). Crystals used in the diffraction experiment were grown by slow evaporation of a CH₂Cl₂ solution.

(E)-4-Nitro-N-(3,4,5-trimethoxybenzylidene)aniline, (III), was prepared by refluxing 3,4,5-trimethoxybenzaldehyde (3.0 g, 0.015 mol) and 4-nitroaniline (2.1 g, 0.015 mol) in methanol (??ml Volume missing?) for 3 h. The resulting yellow precipitate was collected by filtration and recrystallized from acetonitrile, yielding 3.5 g (11 mmol, 75%) of (III). Crystals from this batch were used in the crystallographic experiment. Characterisation: m.p. 428 K; δ¹H 3.94 (s, 3H, 4-OCH₃), 3.95 (s, 6H, 3-OCH₃ and 5-OCH₃), 7.18 (s, 2H, H2 and H6), 7.23 (dd, ³J = 8.9, ⁴J = 1.9, 2H, H10 and H14), 8.25 (dd, ³J = 8.9, ⁴J = 1.9, 2H, H11 and H13), 8.32 (s, 1H, H7); δ¹³C 56.33 (3-OCH₃ and 5-OCH₃), 61.03 (4-OCH₃), 106.44 (C2 and C6), 121.29 (C10 and C14), 125.04 (C11 and C13), 130.81 (C1), 142.01 (C4), 145.45 (C12), 153.65 (C3 and C5), 157.87 (C9), 162.08 (C7).

Computing details top

For all compounds, data collection: CAD-4 EXPRESS (Enraf–Nonius, 1994); cell refinement: CAD-4 EXPRESS (Enraf–Nonius, 1994); data reduction: XCAD4 (Harms & Wocadlo, 1996); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: ORTEP-3 (Farrugia, 1997) and Mercury (Macrae et al., 2008); software used to prepare material for publication: WinGX (Farrugia, 1999) and PLATON (Spek, 2009).

Figures top

	Fig. 1. Polar histograms illustrating the distribution of (a) torsion angles τ(C2—C1—C7—C8) in stilbenes, (b) torsion angles τ(C2—C1—N2—C8) in BAs and (c) torsion angles of donor–acceptor BAs in noncentrosymmetric space groups; see Comment for details.
	Fig. 2. The molecular structures of (I), (II) and (III), showing the atom-numbering scheme. In each case, the nitro-substituted ring is labelled A. Displacement ellipsoids are drawn at the 50% probability level; H atoms are represented by spheres of arbitrary radii and bear the same number as the C atom to which they are attached. Atom N2 replaces either C7 or C8.
	Fig. 3. (a) The corrugated planes in the structure of (I), held together by (b) π–π, (c) OCH₃···π and (d) C—H···O interactions (all interactions shown as dashed lines).
	Fig. 4. (a) The herringbone pattern in the structure of (II), viewed along the a axis, and (b) the various other intermolecular contacts (dashed lines).
	Fig. 5. (a) The NO···π contacts, (b) the interactions within the layers and (c) the layered structure of (III) (all interactions shown as dashed lines).

(I) (E)-1-nitro-4-[2-(3,4,5-trimethoxyphenyl)ethenyl]benzene top

Crystal data top

C₁₇H₁₇NO₅	F(000) = 664
M_r = 315.32	D_x = 1.339 Mg m⁻³
Monoclinic, P2₁/c	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: -P 2ybc	Cell parameters from 25 reflections
a = 10.459 (2) Å	θ = 5.4–10.1°
b = 12.88 (1) Å	µ = 0.10 mm⁻¹
c = 14.021 (4) Å	T = 293 K
β = 124.069 (15)°	Block, yellow
V = 1564.6 (13) Å³	0.42 × 0.39 × 0.39 mm
Z = 4

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.043
Radiation source: fine-focus sealed tube	θ_max = 25.4°, θ_min = 2.4°
Graphite monochromator	h = −12→0
θ/2ω scans	k = −15→15
5901 measured reflections	l = −13→16
2867 independent reflections	3 standard reflections every 60 min
1500 reflections with I > 2σ(I)	intensity decay: none

Refinement top

Refinement on F²	Primary atom site location: structure-invariant direct methods
Least-squares matrix: full	Secondary atom site location: difference Fourier map
R[F² > 2σ(F²)] = 0.045	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.135	H-atom parameters constrained
S = 1.00	w = 1/[σ²(F_o²) + (0.0536P)² + 0.4441P] where P = (F_o² + 2F_c²)/3
2867 reflections	(Δ/σ)_max < 0.001
211 parameters	Δρ_max = 0.35 e Å⁻³
0 restraints	Δρ_min = −0.14 e Å⁻³

Crystal data top

C₁₇H₁₇NO₅	V = 1564.6 (13) Å³
M_r = 315.32	Z = 4
Monoclinic, P2₁/c	Mo Kα radiation
a = 10.459 (2) Å	µ = 0.10 mm⁻¹
b = 12.88 (1) Å	T = 293 K
c = 14.021 (4) Å	0.42 × 0.39 × 0.39 mm
β = 124.069 (15)°

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.043
5901 measured reflections	3 standard reflections every 60 min
2867 independent reflections	intensity decay: none
1500 reflections with I > 2σ(I)

Refinement top

R[F² > 2σ(F²)] = 0.045	0 restraints
wR(F²) = 0.135	H-atom parameters constrained
S = 1.00	Δρ_max = 0.35 e Å⁻³
2867 reflections	Δρ_min = −0.14 e Å⁻³
211 parameters

Special details top

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

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

	x	y	z	U_iso*/U_eq
C1	0.2949 (3)	0.6123 (2)	0.0449 (2)	0.0500 (6)
C2	0.2913 (3)	0.55632 (19)	−0.0414 (2)	0.0512 (6)
H2	0.2611	0.4870	−0.0537	0.061*
C3	0.3328 (3)	0.6036 (2)	−0.1089 (2)	0.0500 (6)
C4	0.3792 (3)	0.70753 (19)	−0.0895 (2)	0.0484 (6)
C5	0.3820 (3)	0.7628 (2)	−0.0030 (2)	0.0519 (6)
C6	0.3401 (3)	0.7153 (2)	0.0635 (2)	0.0532 (7)
H6	0.3422	0.7526	0.1212	0.064*
C7	0.2517 (3)	0.5678 (2)	0.1199 (2)	0.0592 (7)
H7	0.2756	0.6078	0.1832	0.071*
C8	0.1847 (3)	0.4801 (2)	0.1088 (2)	0.0583 (7)
H8	0.1619	0.4384	0.0470	0.070*
C9	0.1411 (3)	0.4402 (2)	0.1861 (2)	0.0512 (6)
C14	0.0873 (3)	0.3402 (2)	0.1730 (2)	0.0595 (7)
H14	0.0774	0.2988	0.1148	0.071*
C13	0.0482 (3)	0.3004 (2)	0.2437 (2)	0.0585 (7)
H13	0.0135	0.2323	0.2346	0.070*
C12	0.0607 (3)	0.3618 (2)	0.3282 (2)	0.0520 (6)
C11	0.1111 (3)	0.4624 (2)	0.3438 (2)	0.0609 (7)
H11	0.1174	0.5036	0.4008	0.073*
C10	0.1525 (3)	0.5014 (2)	0.2726 (2)	0.0597 (7)
H10	0.1884	0.5693	0.2826	0.072*
C31	0.2920 (4)	0.4510 (2)	−0.2184 (3)	0.0751 (9)
H31A	0.1897	0.4416	−0.2362	0.113*
H31B	0.3638	0.4110	−0.1514	0.113*
H31C	0.2949	0.4283	−0.2823	0.113*
C51	0.4430 (4)	0.9222 (2)	0.1004 (3)	0.0788 (9)
H51A	0.5192	0.8903	0.1724	0.118*
H51B	0.3457	0.9238	0.0924	0.118*
H51C	0.4744	0.9918	0.0985	0.118*
C411	0.5782 (4)	0.7551 (3)	−0.1094 (3)	0.0818 (9)
H41A	0.6136	0.6847	−0.1002	0.123*
H41B	0.6322	0.7889	−0.0357	0.123*
H41C	0.5977	0.7914	−0.1598	0.123*
N1	0.0198 (3)	0.3190 (2)	0.4046 (2)	0.0728 (7)
O1	0.0234 (3)	0.3758 (2)	0.4752 (2)	0.1155 (9)
O2	−0.0113 (3)	0.2273 (2)	0.3958 (2)	0.1119 (9)
O3	0.3325 (2)	0.55781 (14)	−0.19659 (15)	0.0661 (5)
O4	0.4183 (2)	0.75565 (14)	−0.15702 (14)	0.0608 (5)
O5	0.4280 (2)	0.86429 (14)	0.00886 (15)	0.0674 (5)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.0453 (14)	0.0654 (17)	0.0449 (14)	0.0061 (12)	0.0287 (12)	0.0104 (13)
C2	0.0459 (15)	0.0497 (15)	0.0569 (16)	0.0024 (12)	0.0281 (13)	0.0088 (12)
C3	0.0458 (15)	0.0592 (16)	0.0446 (14)	0.0073 (12)	0.0250 (12)	0.0042 (12)
C4	0.0478 (14)	0.0559 (16)	0.0432 (14)	0.0040 (12)	0.0265 (12)	0.0100 (12)
C5	0.0481 (15)	0.0570 (16)	0.0473 (14)	0.0031 (12)	0.0248 (13)	0.0079 (12)
C6	0.0537 (16)	0.0597 (17)	0.0475 (14)	0.0027 (13)	0.0292 (14)	0.0038 (12)
C7	0.0519 (16)	0.0617 (18)	0.0607 (17)	0.0000 (14)	0.0294 (14)	0.0001 (13)
C8	0.0518 (16)	0.0615 (18)	0.0579 (16)	0.0043 (14)	0.0285 (14)	−0.0023 (13)
C9	0.0461 (14)	0.0636 (17)	0.0455 (14)	0.0050 (13)	0.0268 (12)	0.0059 (13)
C14	0.0625 (18)	0.0555 (17)	0.0632 (17)	−0.0007 (13)	0.0369 (16)	−0.0034 (13)
C13	0.0585 (17)	0.0536 (16)	0.0637 (17)	−0.0044 (13)	0.0344 (15)	0.0055 (14)
C12	0.0480 (15)	0.0616 (17)	0.0459 (15)	−0.0041 (13)	0.0260 (12)	0.0095 (13)
C11	0.0643 (18)	0.0645 (18)	0.0527 (16)	−0.0069 (14)	0.0321 (15)	−0.0042 (13)
C10	0.0614 (17)	0.0510 (15)	0.0682 (18)	−0.0087 (13)	0.0371 (15)	0.0068 (14)
C31	0.083 (2)	0.0676 (19)	0.076 (2)	0.0016 (16)	0.0458 (18)	−0.0132 (16)
C51	0.094 (2)	0.0665 (19)	0.0691 (19)	−0.0079 (18)	0.0413 (18)	−0.0118 (16)
C411	0.069 (2)	0.108 (3)	0.084 (2)	−0.0072 (18)	0.0520 (18)	0.0097 (19)
N1	0.0767 (18)	0.0812 (19)	0.0606 (16)	−0.0120 (15)	0.0385 (14)	0.0113 (14)
O1	0.172 (3)	0.122 (2)	0.0974 (18)	−0.0251 (19)	0.103 (2)	−0.0089 (16)
O2	0.155 (3)	0.0953 (19)	0.1022 (18)	−0.0450 (17)	0.0825 (19)	0.0046 (14)
O3	0.0825 (14)	0.0673 (12)	0.0597 (11)	−0.0036 (10)	0.0467 (11)	−0.0081 (10)
O4	0.0672 (13)	0.0707 (12)	0.0515 (10)	0.0000 (9)	0.0377 (10)	0.0141 (9)
O5	0.0890 (14)	0.0547 (11)	0.0653 (12)	−0.0062 (10)	0.0474 (11)	−0.0016 (9)

Geometric parameters (Å, º) top

C1—C6	1.383 (4)	C13—H13	0.9300
C1—C2	1.392 (3)	C12—C11	1.369 (4)
C1—C7	1.474 (3)	C12—N1	1.464 (3)
C2—C3	1.384 (3)	C11—C10	1.387 (3)
C2—H2	0.9300	C11—H11	0.9300
C3—O3	1.362 (3)	C10—H10	0.9300
C3—C4	1.398 (4)	C31—O3	1.421 (3)
C4—O4	1.372 (3)	C31—H31A	0.9600
C4—C5	1.392 (3)	C31—H31B	0.9600
C5—O5	1.370 (3)	C31—H31C	0.9600
C5—C6	1.377 (3)	C51—O5	1.415 (3)
C6—H6	0.9300	C51—H51A	0.9600
C7—C8	1.291 (4)	C51—H51B	0.9600
C7—H7	0.9300	C51—H51C	0.9600
C8—C9	1.484 (3)	C411—O4	1.411 (3)
C8—H8	0.9300	C411—H41A	0.9600
C9—C14	1.377 (4)	C411—H41B	0.9600
C9—C10	1.394 (3)	C411—H41C	0.9600
C14—C13	1.366 (4)	N1—O2	1.214 (3)
C14—H14	0.9300	N1—O1	1.215 (3)
C13—C12	1.369 (4)

C6—C1—C2	120.0 (2)	C13—C12—C11	121.8 (2)
C6—C1—C7	116.6 (2)	C13—C12—N1	119.3 (3)
C2—C1—C7	123.3 (2)	C11—C12—N1	118.9 (3)
C3—C2—C1	120.1 (2)	C12—C11—C10	118.4 (3)
C3—C2—H2	120.0	C12—C11—H11	120.8
C1—C2—H2	120.0	C10—C11—H11	120.8
O3—C3—C2	125.7 (2)	C11—C10—C9	120.8 (3)
O3—C3—C4	114.6 (2)	C11—C10—H10	119.6
C2—C3—C4	119.7 (2)	C9—C10—H10	119.6
O4—C4—C5	120.1 (2)	O3—C31—H31A	109.5
O4—C4—C3	120.2 (2)	O3—C31—H31B	109.5
C5—C4—C3	119.7 (2)	H31A—C31—H31B	109.5
O5—C5—C6	124.4 (2)	O3—C31—H31C	109.5
O5—C5—C4	115.4 (2)	H31A—C31—H31C	109.5
C6—C5—C4	120.2 (3)	H31B—C31—H31C	109.5
C5—C6—C1	120.2 (2)	O5—C51—H51A	109.5
C5—C6—H6	119.9	O5—C51—H51B	109.5
C1—C6—H6	119.9	H51A—C51—H51B	109.5
C8—C7—C1	128.1 (3)	O5—C51—H51C	109.5
C8—C7—H7	116.0	H51A—C51—H51C	109.5
C1—C7—H7	116.0	H51B—C51—H51C	109.5
C7—C8—C9	125.6 (3)	O4—C411—H41A	109.5
C7—C8—H8	117.2	O4—C411—H41B	109.5
C9—C8—H8	117.2	H41A—C411—H41B	109.5
C14—C9—C10	118.4 (2)	O4—C411—H41C	109.5
C14—C9—C8	119.8 (2)	H41A—C411—H41C	109.5
C10—C9—C8	121.8 (2)	H41B—C411—H41C	109.5
C13—C14—C9	121.3 (3)	O2—N1—O1	123.6 (3)
C13—C14—H14	119.3	O2—N1—C12	117.6 (3)
C9—C14—H14	119.3	O1—N1—C12	118.8 (3)
C14—C13—C12	119.3 (3)	C3—O3—C31	117.5 (2)
C14—C13—H13	120.3	C4—O4—C411	113.8 (2)
C12—C13—H13	120.3	C5—O5—C51	117.8 (2)

C6—C1—C2—C3	−0.1 (4)	C10—C9—C14—C13	−1.1 (4)
C7—C1—C2—C3	179.7 (2)	C8—C9—C14—C13	179.0 (2)
C1—C2—C3—O3	−179.2 (2)	C9—C14—C13—C12	1.0 (4)
C1—C2—C3—C4	0.4 (3)	C14—C13—C12—C11	0.1 (4)
O3—C3—C4—O4	0.7 (3)	C14—C13—C12—N1	−179.6 (2)
C2—C3—C4—O4	−179.0 (2)	C13—C12—C11—C10	−1.0 (4)
O3—C3—C4—C5	179.1 (2)	N1—C12—C11—C10	178.7 (2)
C2—C3—C4—C5	−0.6 (3)	C12—C11—C10—C9	0.9 (4)
O4—C4—C5—O5	−1.1 (3)	C14—C9—C10—C11	0.2 (4)
C3—C4—C5—O5	−179.5 (2)	C8—C9—C10—C11	−180.0 (2)
O4—C4—C5—C6	178.8 (2)	C13—C12—N1—O2	6.1 (4)
C3—C4—C5—C6	0.4 (4)	C11—C12—N1—O2	−173.6 (3)
O5—C5—C6—C1	179.9 (2)	C13—C12—N1—O1	−176.1 (3)
C4—C5—C6—C1	0.0 (4)	C11—C12—N1—O1	4.2 (4)
C2—C1—C6—C5	−0.1 (4)	C2—C3—O3—C31	−2.6 (4)
C7—C1—C6—C5	−179.9 (2)	C4—C3—O3—C31	177.8 (2)
C6—C1—C7—C8	168.7 (3)	C5—C4—O4—C411	86.2 (3)
C2—C1—C7—C8	−11.1 (4)	C3—C4—O4—C411	−95.4 (3)
C1—C7—C8—C9	−178.7 (2)	C6—C5—O5—C51	4.3 (4)
C7—C8—C9—C14	−172.1 (3)	C4—C5—O5—C51	−175.8 (2)
C7—C8—C9—C10	8.0 (4)

(II) (E)-3,4,5-trimethoxy-N-(4-nitrobenzylidene)aniline top

Crystal data top

C₁₆H₁₆N₂O₅	F(000) = 664
M_r = 316.31	D_x = 1.385 Mg m⁻³
Monoclinic, P2₁/c	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: -P 2ybc	Cell parameters from 25 reflections
a = 7.512 (2) Å	θ = 5.4–14.7°
b = 7.895 (1) Å	µ = 0.10 mm⁻¹
c = 26.441 (6) Å	T = 293 K
β = 104.667 (19)°	Block, yellow
V = 1517.0 (6) Å³	0.3 × 0.3 × 0.3 mm
Z = 4

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.052
Radiation source: fine-focus sealed tube	θ_max = 25.6°, θ_min = 1.6°
Graphite monochromator	h = 0→9
θ/2ω scans	k = −9→9
5826 measured reflections	l = −31→30
2803 independent reflections	3 standard reflections every 60 min
2023 reflections with I > 2σ(I)	intensity decay: 4%

Refinement top

Refinement on F²	Primary atom site location: structure-invariant direct methods
Least-squares matrix: full	Secondary atom site location: difference Fourier map
R[F² > 2σ(F²)] = 0.036	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.104	H-atom parameters constrained
S = 1.05	w = 1/[σ²(F_o²) + (0.0418P)² + 0.3031P] where P = (F_o² + 2F_c²)/3
2803 reflections	(Δ/σ)_max < 0.001
211 parameters	Δρ_max = 0.14 e Å⁻³
0 restraints	Δρ_min = −0.18 e Å⁻³

Crystal data top

C₁₆H₁₆N₂O₅	V = 1517.0 (6) Å³
M_r = 316.31	Z = 4
Monoclinic, P2₁/c	Mo Kα radiation
a = 7.512 (2) Å	µ = 0.10 mm⁻¹
b = 7.895 (1) Å	T = 293 K
c = 26.441 (6) Å	0.3 × 0.3 × 0.3 mm
β = 104.667 (19)°

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.052
5826 measured reflections	3 standard reflections every 60 min
2803 independent reflections	intensity decay: 4%
2023 reflections with I > 2σ(I)

Refinement top

R[F² > 2σ(F²)] = 0.036	0 restraints
wR(F²) = 0.104	H-atom parameters constrained
S = 1.05	Δρ_max = 0.14 e Å⁻³
2803 reflections	Δρ_min = −0.18 e Å⁻³
211 parameters

Special details top

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

	x	y	z	U_iso*/U_eq
C1	1.0234 (2)	0.87162 (19)	0.66274 (6)	0.0420 (4)
C2	1.0351 (2)	0.88660 (19)	0.71593 (6)	0.0429 (4)
H2	0.9496	0.9513	0.7274	0.051*
C3	1.1754 (2)	0.80434 (18)	0.75161 (6)	0.0410 (3)
C4	1.3010 (2)	0.70573 (19)	0.73430 (6)	0.0430 (4)
C5	1.2858 (2)	0.6907 (2)	0.68100 (6)	0.0447 (4)
C6	1.1481 (2)	0.7743 (2)	0.64526 (6)	0.0451 (4)
H6	1.1395	0.7651	0.6097	0.054*
C8	0.7306 (2)	0.9767 (2)	0.62901 (6)	0.0478 (4)
H8	0.7022	0.9309	0.6584	0.057*
C9	0.5866 (2)	1.0666 (2)	0.59074 (6)	0.0450 (4)
C10	0.6235 (2)	1.1632 (2)	0.55095 (6)	0.0507 (4)
H10	0.7436	1.1733	0.5479	0.061*
C11	0.4829 (2)	1.2443 (2)	0.51605 (7)	0.0540 (4)
H11	0.5071	1.3106	0.4895	0.065*
C12	0.3055 (2)	1.2262 (2)	0.52080 (6)	0.0505 (4)
C13	0.2643 (2)	1.1313 (2)	0.55953 (7)	0.0562 (4)
H13	0.1435	1.1196	0.5619	0.067*
C14	0.4064 (2)	1.0538 (2)	0.59465 (7)	0.0541 (4)
H14	0.3815	0.9911	0.6218	0.065*
C31	1.0868 (3)	0.9150 (3)	0.82531 (7)	0.0651 (5)
H31A	1.0963	1.0300	0.8145	0.098*
H31B	1.1227	0.9087	0.8628	0.098*
H31C	0.9620	0.8769	0.8128	0.098*
C41	1.6137 (2)	0.6981 (3)	0.77813 (8)	0.0659 (5)
H41A	1.6533	0.6931	0.7464	0.099*
H41B	1.6999	0.6383	0.8052	0.099*
H41C	1.6073	0.8142	0.7883	0.099*
C51	1.3954 (3)	0.5540 (3)	0.61467 (8)	0.0830 (7)
H51A	1.2752	0.5076	0.6001	0.124*
H51B	1.4871	0.4730	0.6114	0.124*
H51C	1.4101	0.6557	0.5962	0.124*
N1	0.1548 (3)	1.3158 (2)	0.48429 (6)	0.0671 (4)
N2	0.89150 (18)	0.95908 (17)	0.62363 (5)	0.0478 (3)
O1	0.1956 (2)	1.4109 (2)	0.45293 (6)	0.0940 (5)
O2	−0.0028 (2)	1.2896 (2)	0.48683 (6)	0.0906 (5)
O3	1.20364 (15)	0.81114 (14)	0.80444 (4)	0.0525 (3)
O4	1.43646 (15)	0.62201 (14)	0.76993 (4)	0.0538 (3)
O5	1.41580 (17)	0.59177 (16)	0.66791 (5)	0.0627 (4)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.0435 (8)	0.0387 (8)	0.0430 (8)	−0.0062 (7)	0.0098 (7)	0.0015 (7)
C2	0.0437 (8)	0.0388 (8)	0.0475 (9)	0.0004 (7)	0.0140 (7)	−0.0018 (7)
C3	0.0483 (8)	0.0352 (8)	0.0408 (8)	−0.0039 (7)	0.0137 (7)	−0.0018 (6)
C4	0.0464 (8)	0.0351 (8)	0.0485 (9)	−0.0003 (7)	0.0135 (7)	0.0030 (7)
C5	0.0482 (9)	0.0386 (8)	0.0504 (9)	−0.0014 (7)	0.0181 (7)	−0.0039 (7)
C6	0.0510 (9)	0.0451 (9)	0.0412 (9)	−0.0067 (7)	0.0151 (7)	−0.0029 (7)
C8	0.0523 (9)	0.0471 (9)	0.0435 (9)	−0.0059 (8)	0.0110 (7)	0.0028 (7)
C9	0.0505 (9)	0.0439 (9)	0.0397 (8)	−0.0061 (7)	0.0100 (7)	−0.0027 (7)
C10	0.0502 (9)	0.0560 (10)	0.0471 (9)	−0.0036 (8)	0.0148 (7)	0.0010 (8)
C11	0.0682 (11)	0.0541 (10)	0.0407 (9)	−0.0026 (9)	0.0159 (8)	0.0035 (8)
C12	0.0572 (10)	0.0501 (9)	0.0390 (9)	0.0026 (8)	0.0027 (7)	−0.0053 (7)
C13	0.0477 (9)	0.0641 (11)	0.0556 (11)	−0.0035 (8)	0.0105 (8)	−0.0001 (9)
C14	0.0531 (10)	0.0589 (11)	0.0513 (10)	−0.0063 (8)	0.0151 (8)	0.0082 (8)
C31	0.0720 (12)	0.0773 (13)	0.0473 (10)	0.0197 (10)	0.0176 (9)	−0.0079 (9)
C41	0.0532 (10)	0.0672 (12)	0.0713 (13)	0.0139 (9)	0.0047 (9)	0.0011 (10)
C51	0.1043 (17)	0.0874 (16)	0.0638 (13)	0.0250 (13)	0.0334 (12)	−0.0185 (12)
N1	0.0748 (11)	0.0689 (11)	0.0483 (9)	0.0102 (9)	−0.0016 (8)	−0.0060 (8)
N2	0.0493 (8)	0.0477 (8)	0.0455 (8)	−0.0018 (6)	0.0104 (6)	0.0008 (6)
O1	0.1057 (12)	0.0869 (11)	0.0763 (11)	0.0074 (9)	−0.0015 (9)	0.0302 (9)
O2	0.0629 (9)	0.1285 (15)	0.0722 (11)	0.0233 (9)	0.0020 (7)	0.0061 (9)
O3	0.0620 (7)	0.0543 (7)	0.0419 (6)	0.0137 (6)	0.0148 (5)	0.0003 (5)
O4	0.0585 (7)	0.0473 (7)	0.0558 (7)	0.0111 (6)	0.0146 (6)	0.0092 (5)
O5	0.0701 (8)	0.0660 (8)	0.0562 (8)	0.0169 (6)	0.0239 (6)	−0.0077 (6)

Geometric parameters (Å, º) top

C1—C6	1.379 (2)	C11—H11	0.9300
C1—C2	1.392 (2)	C12—C13	1.366 (2)
C1—N2	1.417 (2)	C12—N1	1.470 (2)
C2—C3	1.385 (2)	C13—C14	1.369 (2)
C2—H2	0.9300	C13—H13	0.9300
C3—O3	1.3598 (18)	C14—H14	0.9300
C3—C4	1.388 (2)	C31—O3	1.4115 (19)
C4—O4	1.3690 (19)	C31—H31A	0.9600
C4—C5	1.390 (2)	C31—H31B	0.9600
C5—O5	1.3618 (19)	C31—H31C	0.9600
C5—C6	1.380 (2)	C41—O4	1.427 (2)
C6—H6	0.9300	C41—H41A	0.9600
C8—N2	1.260 (2)	C41—H41B	0.9600
C8—C9	1.464 (2)	C41—H41C	0.9600
C8—H8	0.9300	C51—O5	1.409 (2)
C9—C10	1.383 (2)	C51—H51A	0.9600
C9—C14	1.387 (2)	C51—H51B	0.9600
C10—C11	1.372 (2)	C51—H51C	0.9600
C10—H10	0.9300	N1—O1	1.214 (2)
C11—C12	1.377 (2)	N1—O2	1.221 (2)

C6—C1—C2	120.76 (14)	C11—C12—N1	119.50 (17)
C6—C1—N2	115.83 (14)	C12—C13—C14	117.87 (16)
C2—C1—N2	123.35 (14)	C12—C13—H13	121.1
C3—C2—C1	119.42 (14)	C14—C13—H13	121.1
C3—C2—H2	120.3	C13—C14—C9	121.68 (16)
C1—C2—H2	120.3	C13—C14—H14	119.2
O3—C3—C2	125.11 (14)	C9—C14—H14	119.2
O3—C3—C4	114.75 (14)	O3—C31—H31A	109.5
C2—C3—C4	120.14 (14)	O3—C31—H31B	109.5
O4—C4—C3	119.54 (14)	H31A—C31—H31B	109.5
O4—C4—C5	120.84 (14)	O3—C31—H31C	109.5
C3—C4—C5	119.61 (14)	H31A—C31—H31C	109.5
O5—C5—C6	124.18 (15)	H31B—C31—H31C	109.5
O5—C5—C4	115.24 (14)	O4—C41—H41A	109.5
C6—C5—C4	120.57 (14)	O4—C41—H41B	109.5
C1—C6—C5	119.49 (15)	H41A—C41—H41B	109.5
C1—C6—H6	120.3	O4—C41—H41C	109.5
C5—C6—H6	120.3	H41A—C41—H41C	109.5
N2—C8—C9	122.52 (15)	H41B—C41—H41C	109.5
N2—C8—H8	118.7	O5—C51—H51A	109.5
C9—C8—H8	118.7	O5—C51—H51B	109.5
C10—C9—C14	118.93 (15)	H51A—C51—H51B	109.5
C10—C9—C8	122.55 (15)	O5—C51—H51C	109.5
C14—C9—C8	118.52 (15)	H51A—C51—H51C	109.5
C11—C10—C9	120.05 (16)	H51B—C51—H51C	109.5
C11—C10—H10	120.0	O1—N1—O2	123.94 (18)
C9—C10—H10	120.0	O1—N1—C12	117.43 (18)
C10—C11—C12	119.21 (16)	O2—N1—C12	118.62 (18)
C10—C11—H11	120.4	C8—N2—C1	119.00 (14)
C12—C11—H11	120.4	C3—O3—C31	118.29 (13)
C13—C12—C11	122.23 (16)	C4—O4—C41	113.80 (13)
C13—C12—N1	118.25 (17)	C5—O5—C51	118.16 (15)

C6—C1—C2—C3	0.8 (2)	C10—C11—C12—C13	0.6 (3)
N2—C1—C2—C3	−176.13 (14)	C10—C11—C12—N1	178.61 (16)
C1—C2—C3—O3	178.86 (14)	C11—C12—C13—C14	0.6 (3)
C1—C2—C3—C4	−1.0 (2)	N1—C12—C13—C14	−177.39 (16)
O3—C3—C4—O4	1.6 (2)	C12—C13—C14—C9	−1.7 (3)
C2—C3—C4—O4	−178.51 (14)	C10—C9—C14—C13	1.5 (3)
O3—C3—C4—C5	−179.60 (14)	C8—C9—C14—C13	−178.48 (17)
C2—C3—C4—C5	0.3 (2)	C13—C12—N1—O1	173.90 (18)
O4—C4—C5—O5	−1.4 (2)	C11—C12—N1—O1	−4.2 (3)
C3—C4—C5—O5	179.79 (13)	C13—C12—N1—O2	−6.7 (3)
O4—C4—C5—C6	179.47 (14)	C11—C12—N1—O2	175.19 (17)
C3—C4—C5—C6	0.7 (2)	C9—C8—N2—C1	179.44 (14)
C2—C1—C6—C5	0.1 (2)	C6—C1—N2—C8	144.52 (15)
N2—C1—C6—C5	177.31 (14)	C2—C1—N2—C8	−38.4 (2)
O5—C5—C6—C1	−179.94 (14)	C2—C3—O3—C31	−2.7 (2)
C4—C5—C6—C1	−0.9 (2)	C4—C3—O3—C31	177.16 (15)
N2—C8—C9—C10	−11.5 (3)	C3—C4—O4—C41	−104.66 (17)
N2—C8—C9—C14	168.44 (16)	C5—C4—O4—C41	76.53 (19)
C14—C9—C10—C11	−0.2 (3)	C6—C5—O5—C51	−8.6 (3)
C8—C9—C10—C11	179.77 (16)	C4—C5—O5—C51	172.27 (17)
C9—C10—C11—C12	−0.8 (3)

(III) (E)-4-nitro-N-(3,4,5-trimethoxybenzylidene)aniline top

Crystal data top

C₁₆H₁₆N₂O₅	F(000) = 664
M_r = 316.31	D_x = 1.383 Mg m⁻³
Orthorhombic, P2₁2₁2₁	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: P 2ac 2ab	Cell parameters from 25 reflections
a = 7.215 (3) Å	θ = 7.2–18.2°
b = 14.429 (2) Å	µ = 0.10 mm⁻¹
c = 14.595 (5) Å	T = 293 K
V = 1519.4 (8) Å³	Prism, yellow
Z = 4	0.4 × 0.4 × 0.3 mm

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.057
Radiation source: fine-focus sealed tube	θ_max = 25.3°, θ_min = 2.0°
Graphite monochromator	h = 0→8
θ/2ω scans	k = −17→17
4683 measured reflections	l = −17→17
1618 independent reflections	3 standard reflections every 60 min
1358 reflections with I > 2σ(I)	intensity decay: 10%

Refinement top

Refinement on F²	Primary atom site location: structure-invariant direct methods
Least-squares matrix: full	Secondary atom site location: difference Fourier map
R[F² > 2σ(F²)] = 0.052	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.141	H-atom parameters constrained
S = 1.07	w = 1/[σ²(F_o²) + (0.1044P)²] where P = (F_o² + 2F_c²)/3
1618 reflections	(Δ/σ)_max < 0.001
212 parameters	Δρ_max = 0.30 e Å⁻³
0 restraints	Δρ_min = −0.21 e Å⁻³

Crystal data top

C₁₆H₁₆N₂O₅	V = 1519.4 (8) Å³
M_r = 316.31	Z = 4
Orthorhombic, P2₁2₁2₁	Mo Kα radiation
a = 7.215 (3) Å	µ = 0.10 mm⁻¹
b = 14.429 (2) Å	T = 293 K
c = 14.595 (5) Å	0.4 × 0.4 × 0.3 mm

Data collection top

Enraf–Nonius CAD-4 diffractometer	R_int = 0.057
4683 measured reflections	3 standard reflections every 60 min
1618 independent reflections	intensity decay: 10%
1358 reflections with I > 2σ(I)

Refinement top

R[F² > 2σ(F²)] = 0.052	0 restraints
wR(F²) = 0.141	H-atom parameters constrained
S = 1.07	Δρ_max = 0.30 e Å⁻³
1618 reflections	Δρ_min = −0.21 e Å⁻³
212 parameters

Special details top

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

	x	y	z	U_iso*/U_eq
C1	−0.0091 (4)	0.48584 (17)	0.05506 (17)	0.0436 (6)
C2	−0.0484 (5)	0.47394 (17)	0.14689 (19)	0.0456 (7)
H2	−0.0801	0.4156	0.1691	0.055*
C3	−0.0406 (4)	0.54894 (19)	0.20568 (19)	0.0462 (7)
C4	0.0069 (4)	0.63696 (17)	0.1717 (2)	0.0455 (7)
C5	0.0429 (4)	0.64850 (17)	0.0790 (2)	0.0466 (7)
C6	0.0359 (4)	0.57333 (18)	0.02054 (19)	0.0466 (7)
H6	0.0610	0.5809	−0.0415	0.056*
C7	−0.0123 (4)	0.40613 (19)	−0.00762 (17)	0.0445 (6)
H7	0.0222	0.4143	−0.0685	0.053*
C9	−0.0694 (4)	0.25169 (17)	−0.04233 (17)	0.0411 (6)
C10	−0.1345 (4)	0.26034 (18)	−0.13153 (18)	0.0468 (7)
H10	−0.1740	0.3178	−0.1528	0.056*
C11	−0.1409 (5)	0.1841 (2)	−0.18876 (17)	0.0499 (7)
H11	−0.1847	0.1893	−0.2485	0.060*
C12	−0.0801 (4)	0.09929 (17)	−0.1548 (2)	0.0455 (7)
C13	−0.0206 (5)	0.08857 (19)	−0.0666 (2)	0.0525 (7)
H13	0.0174	0.0308	−0.0454	0.063*
C14	−0.0178 (5)	0.1647 (2)	−0.0095 (2)	0.0509 (7)
H14	0.0187	0.1579	0.0513	0.061*
C31	−0.1129 (7)	0.4565 (2)	0.3360 (2)	0.0708 (11)
H31A	−0.2171	0.4291	0.3053	0.106*
H31B	−0.1406	0.4633	0.4000	0.106*
H31C	−0.0063	0.4174	0.3287	0.106*
C41	0.1940 (6)	0.7206 (2)	0.2719 (2)	0.0613 (9)
H41A	0.2327	0.6619	0.2963	0.092*
H41B	0.1876	0.7654	0.3205	0.092*
H41C	0.2817	0.7410	0.2267	0.092*
C51	0.0999 (7)	0.7539 (2)	−0.0426 (2)	0.0714 (11)
H51A	0.2034	0.7202	−0.0670	0.107*
H51B	0.1175	0.8189	−0.0530	0.107*
H51C	−0.0118	0.7338	−0.0723	0.107*
N1	−0.0798 (5)	0.01880 (18)	−0.2159 (2)	0.0600 (7)
N2	−0.0612 (4)	0.32647 (16)	0.01965 (15)	0.0444 (6)
O1	−0.1346 (5)	0.02823 (17)	−0.29360 (16)	0.0831 (9)
O2	−0.0239 (5)	−0.05534 (17)	−0.1858 (2)	0.0897 (10)
O3	−0.0755 (4)	0.54563 (14)	0.29720 (12)	0.0604 (6)
O4	0.0162 (4)	0.71109 (13)	0.23073 (14)	0.0572 (6)
O5	0.0860 (4)	0.73709 (14)	0.05276 (15)	0.0608 (7)

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
C1	0.0486 (16)	0.0328 (12)	0.0494 (13)	0.0009 (13)	−0.0048 (13)	−0.0050 (10)
C2	0.0553 (17)	0.0319 (12)	0.0497 (13)	−0.0020 (13)	0.0008 (13)	−0.0043 (11)
C3	0.0523 (17)	0.0378 (14)	0.0485 (13)	0.0027 (13)	−0.0005 (14)	−0.0070 (12)
C4	0.0504 (15)	0.0307 (11)	0.0553 (14)	0.0059 (13)	−0.0029 (14)	−0.0085 (11)
C5	0.0490 (15)	0.0315 (12)	0.0594 (15)	−0.0009 (12)	−0.0032 (13)	0.0008 (11)
C6	0.0575 (17)	0.0372 (13)	0.0451 (12)	−0.0041 (13)	−0.0020 (14)	−0.0027 (11)
C7	0.0527 (15)	0.0398 (13)	0.0411 (12)	−0.0030 (13)	0.0004 (13)	−0.0063 (11)
C9	0.0451 (15)	0.0336 (13)	0.0446 (12)	−0.0033 (12)	0.0017 (11)	−0.0020 (10)
C10	0.0588 (18)	0.0364 (12)	0.0452 (12)	0.0031 (14)	0.0000 (14)	−0.0008 (10)
C11	0.0622 (19)	0.0449 (13)	0.0426 (13)	−0.0045 (14)	−0.0016 (14)	−0.0015 (11)
C12	0.0469 (14)	0.0338 (12)	0.0559 (14)	−0.0075 (13)	0.0046 (13)	−0.0086 (11)
C13	0.0612 (18)	0.0295 (11)	0.0668 (16)	0.0008 (14)	−0.0108 (16)	−0.0010 (12)
C14	0.0626 (17)	0.0400 (13)	0.0500 (14)	−0.0038 (14)	−0.0124 (15)	0.0009 (12)
C31	0.105 (3)	0.0579 (17)	0.0499 (15)	−0.011 (2)	0.010 (2)	0.0023 (15)
C41	0.075 (2)	0.0458 (15)	0.0636 (18)	0.0009 (17)	−0.0075 (17)	−0.0193 (14)
C51	0.090 (3)	0.053 (2)	0.0713 (19)	−0.017 (2)	−0.001 (2)	0.0165 (17)
N1	0.0650 (17)	0.0478 (14)	0.0671 (15)	−0.0104 (15)	0.0034 (14)	−0.0197 (13)
N2	0.0544 (14)	0.0360 (11)	0.0429 (10)	−0.0016 (11)	−0.0007 (11)	−0.0031 (10)
O1	0.122 (3)	0.0680 (15)	0.0594 (13)	−0.0143 (18)	0.0109 (17)	−0.0232 (12)
O2	0.108 (2)	0.0402 (12)	0.120 (2)	0.0076 (14)	−0.025 (2)	−0.0200 (13)
O3	0.0918 (17)	0.0426 (10)	0.0469 (10)	0.0007 (13)	0.0120 (12)	−0.0061 (8)
O4	0.0691 (15)	0.0323 (10)	0.0702 (13)	0.0084 (10)	0.0041 (13)	−0.0179 (9)
O5	0.0841 (17)	0.0314 (10)	0.0668 (12)	−0.0059 (12)	−0.0026 (13)	0.0050 (9)

Geometric parameters (Å, º) top

C1—C2	1.381 (4)	C11—H11	0.9300
C1—C6	1.397 (4)	C12—C13	1.365 (4)
C1—C7	1.470 (3)	C12—N1	1.464 (3)
C2—C3	1.382 (4)	C13—C14	1.378 (4)
C2—H2	0.9300	C13—H13	0.9300
C3—O3	1.360 (3)	C14—H14	0.9300
C3—C4	1.406 (4)	C31—O3	1.431 (4)
C4—O4	1.375 (3)	C31—H31A	0.9600
C4—C5	1.388 (4)	C31—H31B	0.9600
C5—O5	1.370 (3)	C31—H31C	0.9600
C5—C6	1.381 (4)	C41—O4	1.423 (5)
C6—H6	0.9300	C41—H41A	0.9600
C7—N2	1.267 (4)	C41—H41B	0.9600
C7—H7	0.9300	C41—H41C	0.9600
C9—C10	1.389 (4)	C51—O5	1.415 (4)
C9—C14	1.395 (4)	C51—H51A	0.9600
C9—N2	1.409 (3)	C51—H51B	0.9600
C10—C11	1.382 (4)	C51—H51C	0.9600
C10—H10	0.9300	N1—O1	1.209 (4)
C11—C12	1.391 (4)	N1—O2	1.225 (4)

C2—C1—C6	120.7 (2)	C11—C12—N1	118.7 (2)
C2—C1—C7	120.2 (2)	C12—C13—C14	119.0 (3)
C6—C1—C7	119.1 (2)	C12—C13—H13	120.5
C1—C2—C3	119.8 (2)	C14—C13—H13	120.5
C1—C2—H2	120.1	C13—C14—C9	120.3 (2)
C3—C2—H2	120.1	C13—C14—H14	119.8
O3—C3—C2	125.1 (3)	C9—C14—H14	119.8
O3—C3—C4	115.0 (2)	O3—C31—H31A	109.5
C2—C3—C4	119.9 (2)	O3—C31—H31B	109.5
O4—C4—C5	120.5 (2)	H31A—C31—H31B	109.5
O4—C4—C3	119.6 (2)	O3—C31—H31C	109.5
C5—C4—C3	119.9 (2)	H31A—C31—H31C	109.5
O5—C5—C6	124.6 (3)	H31B—C31—H31C	109.5
O5—C5—C4	115.3 (2)	O4—C41—H41A	109.5
C6—C5—C4	120.1 (2)	O4—C41—H41B	109.5
C5—C6—C1	119.7 (2)	H41A—C41—H41B	109.5
C5—C6—H6	120.2	O4—C41—H41C	109.5
C1—C6—H6	120.2	H41A—C41—H41C	109.5
N2—C7—C1	121.3 (2)	H41B—C41—H41C	109.5
N2—C7—H7	119.4	O5—C51—H51A	109.5
C1—C7—H7	119.4	O5—C51—H51B	109.5
C10—C9—C14	119.6 (2)	H51A—C51—H51B	109.5
C10—C9—N2	123.1 (2)	O5—C51—H51C	109.5
C14—C9—N2	117.2 (2)	H51A—C51—H51C	109.5
C11—C10—C9	120.4 (3)	H51B—C51—H51C	109.5
C11—C10—H10	119.8	O1—N1—O2	122.9 (3)
C9—C10—H10	119.8	O1—N1—C12	118.8 (3)
C10—C11—C12	118.3 (2)	O2—N1—C12	118.3 (3)
C10—C11—H11	120.8	C7—N2—C9	120.3 (2)
C12—C11—H11	120.8	C3—O3—C31	117.1 (2)
C13—C12—C11	122.3 (2)	C4—O4—C41	112.6 (2)
C13—C12—N1	119.0 (3)	C5—O5—C51	116.8 (2)

C6—C1—C2—C3	−1.0 (5)	C10—C11—C12—C13	2.2 (5)
C7—C1—C2—C3	178.4 (3)	C10—C11—C12—N1	−177.8 (3)
C1—C2—C3—O3	−179.7 (3)	C11—C12—C13—C14	−1.1 (5)
C1—C2—C3—C4	0.2 (5)	N1—C12—C13—C14	178.9 (3)
O3—C3—C4—O4	0.5 (4)	C12—C13—C14—C9	−2.0 (5)
C2—C3—C4—O4	−179.3 (3)	C10—C9—C14—C13	3.9 (5)
O3—C3—C4—C5	−179.2 (3)	N2—C9—C14—C13	−179.3 (3)
C2—C3—C4—C5	1.0 (5)	C13—C12—N1—O1	179.1 (4)
O4—C4—C5—O5	−0.3 (4)	C11—C12—N1—O1	−0.9 (5)
C3—C4—C5—O5	179.4 (3)	C13—C12—N1—O2	−0.9 (5)
O4—C4—C5—C6	179.0 (3)	C11—C12—N1—O2	179.1 (4)
C3—C4—C5—C6	−1.3 (5)	C1—C7—N2—C9	177.8 (3)
O5—C5—C6—C1	179.8 (3)	C10—C9—N2—C7	−39.5 (4)
C4—C5—C6—C1	0.5 (5)	C14—C9—N2—C7	143.8 (3)
C2—C1—C6—C5	0.6 (5)	C2—C3—O3—C31	3.7 (5)
C7—C1—C6—C5	−178.8 (3)	C4—C3—O3—C31	−176.2 (3)
C2—C1—C7—N2	4.1 (5)	C5—C4—O4—C41	−92.6 (3)
C6—C1—C7—N2	−176.4 (3)	C3—C4—O4—C41	87.8 (4)
C14—C9—C10—C11	−2.7 (5)	C6—C5—O5—C51	8.7 (5)
N2—C9—C10—C11	−179.3 (3)	C4—C5—O5—C51	−172.0 (3)
C9—C10—C11—C12	−0.2 (5)

Experimental details

	(I)	(II)	(III)
Crystal data
Chemical formula	C₁₇H₁₇NO₅	C₁₆H₁₆N₂O₅	C₁₆H₁₆N₂O₅
M_r	315.32	316.31	316.31
Crystal system, space group	Monoclinic, P2₁/c	Monoclinic, P2₁/c	Orthorhombic, P2₁2₁2₁
Temperature (K)	293	293	293
a, b, c (Å)	10.459 (2), 12.88 (1), 14.021 (4)	7.512 (2), 7.895 (1), 26.441 (6)	7.215 (3), 14.429 (2), 14.595 (5)
α, β, γ (°)	90, 124.069 (15), 90	90, 104.667 (19), 90	90, 90, 90
V (Å³)	1564.6 (13)	1517.0 (6)	1519.4 (8)
Z	4	4	4
Radiation type	Mo Kα	Mo Kα	Mo Kα
µ (mm⁻¹)	0.10	0.10	0.10
Crystal size (mm)	0.42 × 0.39 × 0.39	0.3 × 0.3 × 0.3	0.4 × 0.4 × 0.3

Data collection
Diffractometer	Enraf–Nonius CAD-4 diffractometer	Enraf–Nonius CAD-4 diffractometer	Enraf–Nonius CAD-4 diffractometer
Absorption correction	–	–	–
No. of measured, independent and observed [I > 2σ(I)] reflections	5901, 2867, 1500	5826, 2803, 2023	4683, 1618, 1358
R_int	0.043	0.052	0.057
(sin θ/λ)_max (Å⁻¹)	0.602	0.608	0.602

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.045, 0.135, 1.00	0.036, 0.104, 1.05	0.052, 0.141, 1.07
No. of reflections	2867	2803	1618
No. of parameters	211	211	212
H-atom treatment	H-atom parameters constrained	H-atom parameters constrained	H-atom parameters constrained
Δρ_max, Δρ_min (e Å⁻³)	0.35, −0.14	0.14, −0.18	0.30, −0.21

Computer programs: CAD-4 EXPRESS (Enraf–Nonius, 1994), XCAD4 (Harms & Wocadlo, 1996), SHELXS97 (Sheldrick, 2008), SHELXL97 (Sheldrick, 2008), ORTEP-3 (Farrugia, 1997) and Mercury (Macrae et al., 2008), WinGX (Farrugia, 1999) and PLATON (Spek, 2009).

Selected geometric data for (I), (II) and (III): calculated (DFT) and experimental (XRD) torsion angles in degrees, and calculated dipole moments µ in debye top

Compound	Parameter	XRD	DFT	µ
(I)	C2–C1–C7–C8	-11.0 (5)	176.2
	C1–C7–C8–C9	178.7 (3)	0.3	5.48
	C7–C8–C9–C10	-172.1 (3)	4.2
(II)	C2–C1–N2–C8	-38.4 (2)	31.6
	C1–N2–C8–C9	179.4 (1)	177.4	4.59
	N2–C8–C9–C10	-11.5 (2)	1.4
(III)	C2–C1–C7–N2	4.1 (4)	1.4
	C1–C7–N2–C9	177.8 (2)	176.4	6.15
	C7–N2–C9–C10	-39.5 (4)	42.5

List of weak hydrogen bonds in the crystal packing of (I) (Å, °) top

Entry	D	H	A	H···A	D···A	D—H···A
1	C14	H14	O2ⁱⁱ	2.69	3.526 (4)	151
2	C7	H7	O4ⁱⁱⁱ	2.57	3.447 (3)	158
3	C31	H31B	CgB^iv	2.83	3.718 (5)	154

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

List of weak hydrogen bonds in the crystal packing of (II) (Å, °) top

Entry	D	H	A	H···A	D···A	D—H···A
1	C6	H6	O2^v	2.54	3.423 (2)	160
2	C41	H41C	O5^vi	2.50	3.450 (3)	168
3	C41	H41B	CgB^vii	2.96	3.626 (3)	128
4	C31	H31A	CgB^viii	2.78	3.463 (3)	129
5	C31	H31B	O1^ix	2.71	3.542 (3)	145
6	C51	H51B	CgA^x	2.94	3.631 (3)	130

Symmetry codes: (vi) -x + 3, y + 1/2, -z + 3/2; (vii) -x + 3, y - 1/2, -z + 3/2; (viii) -x + 2, y + 1/2, -z + 3/2; (ix) x + 1, -y + 3/2, z + 1/2; (x) x + 1, y - 1, z.

List of short contacts in the crystal packing of (III) (Å, °) top

Entry	D	X	A	X···A	D···A	D—X···A
1	C41	H41B	N2^xi	2.66	3.537 (4)	153
2	C6	H6	O1^xii	2.58	3.450 (4)	156
3	N1	O2	CgB^xiii	3.610 (4)	3.587 (4)	79.1 (2)
4	N1	O2	CgB^xiv	3.912 (4)	4.578 (4)	115.7 (2)

Symmetry codes: (xi) -x, 1/2 + y, 1/2 - z; (xii) -x, 1/2 + y, -1/2 - z; (xiii) -1/2 + x, 1/2 - y, -z; (xiv) 1/2 + x, 1/2 - y, -z.

Acknowledgements

AC thanks the Institute for the Promotion of Innovation by Science and Technology in Flanders (IWT) for his predoctoral grants. Financial support by FWO–Vlaanderen under grant No. G.0129.05 and by the University of Antwerp under grant No. GOA-2404 is gratefully acknowledged.

References

Ajeetha, N. & Pisipati, V. G. K. M. (2006). Mol. Cryst. Liq. Cryst. 457, 3–25. Web of Science CrossRef CAS Google Scholar
Allen, F. H. (2002). Acta Cryst. B58, 380–388. Web of Science CrossRef CAS IUCr Journals Google Scholar
Enraf–Nonius (1994). CAD-4 EXPRESS. Enraf–Nonius, Delft, The Netherlands. Google Scholar
Fakruddin, K., Kumar, R. J., Prasad, P. V. D. & Pisipati, V. G. K. M. (2009). Mol. Cryst. Liq. Cryst. 511, 1616–1627. CAS Google Scholar
Farrugia, L. J. (1997). J. Appl. Cryst. 30, 565. CrossRef IUCr Journals Google Scholar
Farrugia, L. J. (1999). J. Appl. Cryst. 32, 837–838. CrossRef CAS IUCr Journals Google Scholar
Frisch, M. J., et al. (2009). GAUSSIAN09. Revision A.02. Gaussian Inc., Pittsburgh, Pennsylvania, USA. Google Scholar
Harms, K. & Wocadlo, S. (1996). XCAD4. University of Marburg, Germany. Google Scholar
Kitamura, T., Mukoh, A., Isogai, M., Inukai, T., Furukawa, K. & Terashima, K. (1986). Mol. Cryst. Liq. Cryst. 136, 167–173. CrossRef CAS Web of Science Google Scholar
Macrae, C. F., Bruno, I. J., Chisholm, J. A., Edgington, P. R., McCabe, P., Pidcock, E., Rodriguez-Monge, L., Taylor, R., van de Streek, J. & Wood, P. A. (2008). J. Appl. Cryst. 41, 466–470. Web of Science CrossRef CAS IUCr Journals Google Scholar
Neuvonen, H., Neuvonen, K. & Fulop, F. (2006). J. Org. Chem. 71, 3141–3148. Web of Science CrossRef PubMed CAS Google Scholar
Ojala, W. H., Lystad, K. M., Deal, T. L., Engelbretson, J. E., Spude, J. M., Balidemaj, B. & Ojala, C. R. (2009). Cryst. Growth Des. 9, 964–970. Web of Science CSD CrossRef CAS Google Scholar
Schmidt, G. M. J. (1971). Pure Appl. Chem. 27, 647–678. CrossRef CAS Google Scholar
Sheldrick, G. M. (2008). Acta Cryst. A64, 112–122. Web of Science CrossRef CAS IUCr Journals Google Scholar
Spek, A. L. (2009). Acta Cryst. D65, 148–155. Web of Science CrossRef CAS IUCr Journals Google Scholar
Vande Velde, C. M. L., Collas, A., De Borger, R. & Blockhuys, F. (2011). Chem. Eur. J. 17, 912–919. CAS PubMed Google Scholar
Zhang, D.-C. (2002). Acta Cryst. C58, o351–o352. CSD CrossRef CAS IUCr Journals Google Scholar

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ISSN: 2053-2296

Volume 67| Part 9| September 2011| Pages o364-o369

doi:10.1107/S0108270111030952

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organic compounds\(\def\hfill{\hskip 5em}\def\hfil{\hskip 3em}\def\eqno#1{\hfil {#1}}\)

(E)-4-[2-(3,4,5-Trimeth­­oxy­phenyl)ethen­yl]nitro­benzene and its `bridge-flipped' analogues

Comment

Experimental

Compound (I)

Crystal data

Data collection

Refinement

Compound (II)

Crystal data

Data collection

Refinement

Compound (III)

Crystal data

Data collection

Refinement

Supporting information

Acknowledgements

References

organic compounds

(E)-4-[2-(3,4,5-Trimethoxyphenyl)ethenyl]nitrobenzene and its `bridge-flipped' analogues