research communications
Nitrosonium complexation by the tetraphosphonate cavitand 5,11,17,23-tetramethyl-6,10:12,16:18,22:24,4-tetrakis(phenylphosphonato-κ2O,O)resorcin(4)arene
aDipartimento di Scienze Chimiche, della Vita e della Sostenibilità Ambientale, Università di Parma, Parco Area delle Scienze 17/A, 43124 Parma, Italy
*Correspondence e-mail: chiara.massera@unipr.it
The κ2O,O′)resorcin(4)arene and the nitrosyl cation NO+, as the BF4− salt, is reported. The complex, of general formula [(C56H44P4O12)(NO)]BF4·CH2Cl2 or NO@Tiiii[H, CH3, C6H5] BF4·CH2Cl2, crystallizes in the P-1. The nitrosyl cation is disordered over two equivalent positions, with occupancies of 0.503 (2) and 0.497 (2), and interacts with two adjacent P=O groups at the upper rim of the cavitand through dipole–charge interactions. In the lattice, the are connected through a series of C—H⋯π interactions involving the methyl and methylenic H atoms and the aromatic rings of the macrocycle. The structure is further stabilized by the presence of C—H⋯F interactions between the hydrogen atoms of the and the F atoms of the tetrafluoridoborate anion. As a result of the disorder, the lattice dichloromethane molecules could not be modelled in terms of atomic sites, and were treated using the PLATON SQUEEZE procedure [Spek (2015). Acta Cryst. C71, 9–18]. The complexation process has also been studied in solution through NMR titrations.
of a new supramolecular complex between the tetraphosphonate cavitand 5,11,17,23-tetramethyl-6,10:12,16:18,22:24,4-tetrakis(phenylphosphonato-Keywords: crystal structure; tetraphosphonate cavitands; inclusion compounds; nitrosonium ion; C—H⋯F interactions; C—H⋯π interactions.
CCDC reference: 1583086
1. Chemical context
; Cram & Cram, 1994) are synthetic organic compounds endowed with a rigid, pre-organized cavity that have been used extensively both in solution (Hooley & Rebek, 2009; Pochorovski et al., 2012) and in the solid state (Riboni et al., 2016) as molecular receptors for neutral molecules and cationic species (Pinalli & Dalcanale, 2013). This versatility stems from the possibility of decorating both the upper and the lower rim of the resorcinarene skeleton with desired functionalities.
(Cram, 1983In our group, we have been particularly interested in tetraphosphonate R, R1, R2] (R = lower rim substituents; R1 = upper rim substituents; R2 = substituents on the P atom) in which the upper rim of the macrocycle is functionalized with four P=O groups, all pointing inwards towards the cavity (Pinalli & Dalcanale, 2013). In this way, the π basicity of the cavity, useful for C—H⋯π recognition, is enriched with dipolar groups that can act both as hydrogen-bond acceptors and interact with cationic species through cation–dipole interactions.
of the general formula Tiiii[The nitrosonium ion and its salts have been studied in the past to investigate similarities and differences with the O2+ ion in terms of size, oxidation power etc (Mazej et al., 2009). Moreover, the NO+ cation can be used as a model for nitrogen oxides in molecular recognition phenomena. Indeed, the formation of stable, host–guest complexes between NO+ cations and organic molecular receptors has been studied in solution with resorcinarenes (Botta et al., 2007) or with both in solution (Zyryanov et al., 2002, 2003) and in the solid state (Rathore et al., 2000). In particular, nitrosonium hexachloroantimonate was shown to form an with tetramethoxy- and tetra-n-propoxycalix(4)arenes due to the interaction between the positive charge of the guest and the electron-rich aromatic cavity of the host (Rathore et al., 2000). Inspired by this work, we decided to carry out a combined solution and solid-state study of the complexation properties of the rigid tetraphosphonate cavitand 5,11,17,23-tetramethyl-6,10:12,16:18,22:24,4-tetrakis(phenylphosphonato-O,O′)resorcin(4)arene (from now on indicated as Tiiii[H, CH3, C6H5]) towards NOBF4.
2. Studies in solution
Preliminary 31P and 1H NMR studies were performed to probe the complexation properties of the cavitand towards the nitrosonium ion in solution. To this purpose, we synthesized the cavitand Tiiii[C3H7, CH3, C6H5], functionalized at the lower rim with four –C3H7 alkyl chains to enhance the cavitand solubility. The NMR tube was filled with 0.5 ml of a CDCl3 solution containing the cavitand (1 mmol concentration). The NOBF4 titrant solution was prepared by dissolving the guest in 0.4 ml (10 mmol) of the above-mentioned cavitand solution to keep the concentration of the host constant during the titration. Portions (0.25 eq., 22.5 µL) of the titrant were added by syringe to the NMR tube. During the titration, the phosphorous singlet of the cavitand shifted slightly downfield, from 6.01 (signal for the free host) to 7.42 ppm upon addition of an excess (2.5 eq.) of the guest (see Fig. S1 in the Supporting information), indicating the presence of cation–dipole interactions between the nitrosonium ion and the phosphonate groups at the upper rim. The broadening of the signal is due to the fast exchange (at the NMR time scale) of the guest inside the cavity.
In Fig. 1, the comparison between the 1H spectra recorded after each guest addition is reported. As can be seen, the protons of the methyl group in the apical position of the cavitand skeleton (purple dot) are shifted up-field, increasing the guest concentration; this means that the presence of the NO+ cation in proximity to the cavitand upper rim creates a change in the environment, which results in an overall shielding effect. On the contrary, the signals of the protons at the lower rim, namely the aromatic hydrogens (light-blue dot), the bridging methines (green dot) and the alkyl methylenic groups (red dot), are shifted downfield. This is due to the perturbation created by the BF4− anion, which is likely positioned among the alkyl feet of the cavitand, as already observed for counter-anions in other crystal structures previously reported (Pinalli et al., 2016). Also in this case, broadening of the signals was observed.
Following these results, solid-state studies were carried out to obtain an insight into the type, number, strength and geometry of the weak interactions taking place in the system.
3. Structural commentary
The molecular structure of NO@Tiiii[H, CH3, C6H5]BF4·CH2Cl2 is reported in Fig. 2. The complex crystallizes in the P, and the comprises one cavitand, one molecule of NOBF4 (with the cation disordered over two equivalent positions) and one disordered molecule of dichloromethane. The NO+BF4− ionic pair is separated, and the nitrosonium ion is located within the macrocycle, not deep inside the cavity, but lying in the mean plane passing through the four phosphonate oxygen atoms O3A, O3B, O3C and O3D (for detailed geometrical parameters, see Table 1). The nitrogen and oxygen atoms of the guest point towards the lower and the upper rims, respectively, and are held in place via cation–dipole interactions with two adjacent P=O groups. It is interesting to note that the NO+ ion is disordered with 50% probability over two equivalent orientations [N1O1 with occupancy of 0.503 (2) and N2O2 with occupancy of 0.497 (2)], thus forming alternately an interaction with each of the two opposite P=O groups (Fig. 2; the second orientation is not shown), namely P1A=O3A and P1B=O3B for N1O1 and P1C=O3C and P1D=O3D with N2O2 [O3A⋯O1, 2.621 (5); O3A⋯N1, 2.661 (6); O3B⋯O1, 2.609 (3); O3B⋯N1, 2.664 (5); O3C⋯O2, 2.621 (4); O3C⋯N2, 2.625 (7); O3D⋯O2, 2.604 (4); O3D⋯N2, 2.650 (4) Å]. This phenomenon has already been observed in the solid state with phosphonate hosting methanol and ethanol molecules (Melegari et al., 2008) and confirms that, for these systems, the stability of the host–guest complex is entropic in origin, since the guest can choose from two up to four energetically and geometrically equivalent interaction modes with the host. In this case, the NO+ cation forms two sets of strong interactions with two adjacent P=O groups, which results in a better stabilizing effect than four weaker interactions with all the phosphonate moieties of the upper rim. The BF4− ion is outside the cavity, forming weak C—H⋯F interactions with the (see Section 4 for details).
The dichloromethane solvent molecule is heavily disordered and could not be modelled, but its residual electron density, occupying a void of 312 Å3 (Spek, 2015) is located in the hydrophobic pockets among the cavitands.
4. Supramolecular features
In the lattice, the a-axis direction through a series of C—H⋯π interactions between the H atoms of the methyl groups at the upper rim and the phenyl rings of the phosphonato moieties. In particular, each cavitand interacts with two adjacent ones acting simultaneously as a donor to two methyl groups and as an acceptor to two aromatic rings (see Table 2 and Fig. 3; the centroids involved are Cg1 and Cg2, represented as red and green spheres, respectively). Moreover, pairs of centrosymmetric form another set of C—H⋯π interactions involving the methylenic hydrogen atoms at the lower rim and the aromatic walls of the macrocycle (see Table 2 and Fig. 3, Cg3, blue centroids). The structure is further stabilized by the presence of C—H⋯F interactions between the hydrogen atoms of the and the fluorine atoms of the tetrafluoridoborate anion. More precisely, each BF4− is surrounded by five (Fig. 4), with C—H⋯F distances ranging from 2.408 (2) to 2.653 (2) Å (Table 2).
form a supramolecular ribbon along the
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5. Database survey
A search in the Cambridge Structural Database (Version 5.38, update May 2017; Groom et al., 2016) for structures containing the isolated NO fragment, with no restrictions on the charge or on the type of bond connecting nitrogen and oxygen, yielded 65 species which are, of course, very different in nature. Meaningful comparisons with our complex are only possible with the series of calixarene-based, host–guest complexes already cited in the introduction, namely GOTCAT, GOTDEY, GOTGEB, GOTHAY and GOTHAY01 (Rathore et al., 2000) and with a cationic radical calixarene derivative capable of binding neutral nitric oxide (JAHFOO; Rathore et al., 2004). In particular, in GOTCAT, the NO+ cation is buried deep inside the cavity, where it interacts with two distal aromatic groups of the calixarene guest. Since the calixarene is in the 1,3-alternate conformation, two sets of co-facial benzene rings are present, and the NO+ ion is equally distributed between them (see Fig. 5, one pair of rings is shown in space-filling model, the other one in capped-stick mode). The electron-rich pocket formed by the co-facial pair is essential for the complexation, and the NO+ ion is not bound by a single aromatic ring alone (see, for instance, GOTDEY and GOTGEB). In the case of JAHFOO, the calixarene has been oxidized to carry an overall positive charge on its core, in order to make it a good receptor for an electron rich-guest such as nitric oxide. Nevertheless, the interaction mode is similar to that observed for GOTCAT, with two disordered NO molecules buried between two distinct pairs of distal aromatic rings (Fig. 5). Also, in the title complex the guest is disordered over two equivalent positions, but its interaction with the electron-rich cavity is negligible due to the presence of the dipolar phosphonate groups which `hold' the NO+ ion at the brim of the upper rim (Fig. 5).
6. Synthesis and crystallization
1H NMR spectra were obtained using a Bruker AMX-400 (400 MHz) spectrometer. All chemical shifts (δ) were reported in ppm relative to the proton resonances resulting from incomplete deuteration of the NMR solvents. 31P NMR spectra were obtained using a Bruker AMX-400 (162 MHz) spectrometer. All chemical shifts (δ) were recorded in ppm relative to external 85% H3PO4 at 0.00 ppm. All commercial reagents were ACS reagent grade and used as received. The Tiiii[H, CH3, C6H5] and Tiiii[C3H7, CH3, C6H5] were prepared following published procedures (Tonezzer et al., 2008; Menozzi et al., 2015).
NO@Tiiii[H, CH3, C6H5]BF4·CH2Cl2 was obtained by mixing a dichloromethane solution of Tiiii[H, CH3, C6H5] (1 eq.) with a dichloromethane solution of NOBF4 (1 eq.). The mixture was left to evaporate to yield colourless single crystals of the 1:1 complex that were suitable for X-ray diffraction analysis.
7. Refinement
Crystal data, data collection and structure . The nitrosonium ion was found to be disordered over two positions, with a refined occupancy ratio of 0.503 (2):0.497 (2). The C-bound H atoms were placed in calculated positions and refined using a riding model: C—H = 0.95-0.98 Å with Uiso(H) = 1.5Ueq(C-methyl) and 1.2Ueq(C) for other H atoms.
details are summarized in Table 3
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As a result of severe disorder, the CH2Cl2 solvent could not be sensibly modelled in terms of atomic sites, and was treated using the PLATON SQUEEZE procedure (Spek, 2015); the solvent contribution to the diffraction pattern was removed and modified Fo2 written to a new HKL file. The number of electrons corresponding to the solvent molecules were included in the formula, formula weight, calculated density, μ and F(000).
Supporting information
CCDC reference: 1583086
https://doi.org/10.1107/S2056989017015857/su5400sup1.cif
contains datablocks I, Global. DOI:Structure factors: contains datablock I. DOI: https://doi.org/10.1107/S2056989017015857/su5400Isup2.hkl
Figure showing the 31P NMR (162 MHz, CDCl3, 298 K) spectra recorded during the titration of the cavitand with increasing equivalents of NOBF4. DOI: https://doi.org/10.1107/S2056989017015857/su5400sup3.tif
Data collection: APEX2 (Bruker, 2008); cell
APEX2 (Bruker, 2008); data reduction: SAINT (Bruker, 2008); program(s) used to solve structure: SIR97 (Altomare et al., 1999); program(s) used to refine structure: SHELXL2014 (Sheldrick, 2015); molecular graphics: Mercury (Macrae et al., 2008); software used to prepare material for publication: WinGX (Farrugia, 2012), PARST (Nardelli, 1995) and publCIF (Westrip, 2010).C56H44P4O12·NO+·BF4−·CH2Cl2 | Z = 2 |
Mr = 1234.54 | F(000) = 1268 |
Triclinic, P1 | Dx = 1.429 Mg m−3 |
a = 13.856 (1) Å | Mo Kα radiation, λ = 0.71069 Å |
b = 14.909 (2) Å | Cell parameters from 250 reflections |
c = 16.357 (2) Å | θ = 1.5–29.4° |
α = 63.224 (2)° | µ = 0.30 mm−1 |
β = 73.137 (2)° | T = 190 K |
γ = 88.093 (2)° | Prismatic, colourless |
V = 2868.2 (6) Å3 | 0.16 × 0.13 × 0.10 mm |
Bruker SMART BREEZE CCD area-detector diffractometer | 14109 independent reflections |
Radiation source: fine-focus sealed tube | 9478 reflections with I > 2σ(I) |
Graphite monochromator | Rint = 0.033 |
ω scan | θmax = 29.4°, θmin = 1.5° |
Absorption correction: multi-scan (SADABS; Bruker, 2008) | h = −18→18 |
Tmin = 0.812, Tmax = 1.000 | k = −20→20 |
36384 measured reflections | l = −22→22 |
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)] = 0.042 | Hydrogen site location: inferred from neighbouring sites |
wR(F2) = 0.128 | H-atom parameters constrained |
S = 1.00 | w = 1/[σ2(Fo2) + (0.0693P)2] where P = (Fo2 + 2Fc2)/3 |
14109 reflections | (Δ/σ)max = 0.001 |
735 parameters | Δρmax = 0.63 e Å−3 |
0 restraints | Δρmin = −0.41 e Å−3 |
Experimental. The calculated molar mass, density and absorption coefficient include two disordered dichloromethane molecules per cell which do not appear in the final files because of the refinements carried out with data subjected to SQUEEZE. |
Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes. |
x | y | z | Uiso*/Ueq | Occ. (<1) | |
N1 | 0.3415 (3) | 0.7159 (4) | 0.4179 (3) | 0.0386 (10) | 0.503 (2) |
O1 | 0.3391 (2) | 0.6435 (3) | 0.4543 (2) | 0.0307 (8) | 0.503 (2) |
N2 | 0.2020 (3) | 0.7031 (4) | 0.3846 (3) | 0.0426 (11) | 0.497 (2) |
O2 | 0.1903 (2) | 0.6363 (3) | 0.4165 (2) | 0.0266 (7) | 0.497 (2) |
B1 | 0.2882 (2) | 0.2304 (2) | 0.12591 (19) | 0.0410 (6) | |
F1 | 0.34181 (17) | 0.16872 (13) | 0.18534 (15) | 0.0875 (6) | |
F2 | 0.28773 (14) | 0.19718 (12) | 0.05981 (11) | 0.0638 (4) | |
F3 | 0.33203 (12) | 0.32872 (10) | 0.08112 (10) | 0.0553 (4) | |
F4 | 0.19008 (14) | 0.22111 (13) | 0.18451 (14) | 0.0790 (6) | |
P1A | 0.35319 (4) | 0.75850 (4) | 0.63016 (3) | 0.02411 (12) | |
P1B | 0.60883 (4) | 0.73524 (4) | 0.25305 (4) | 0.02623 (12) | |
P1C | 0.19872 (4) | 0.71498 (4) | 0.14576 (3) | 0.02352 (11) | |
P1D | −0.05960 (4) | 0.73655 (4) | 0.52317 (4) | 0.02430 (12) | |
O1A | 0.26652 (10) | 0.82864 (10) | 0.64092 (9) | 0.0264 (3) | |
O2A | 0.45495 (10) | 0.83412 (10) | 0.56545 (9) | 0.0256 (3) | |
O3A | 0.33168 (11) | 0.69279 (11) | 0.59071 (10) | 0.0315 (3) | |
O1B | 0.64868 (10) | 0.81454 (11) | 0.27975 (10) | 0.0286 (3) | |
O2B | 0.60145 (10) | 0.80000 (11) | 0.14780 (9) | 0.0275 (3) | |
O3B | 0.51418 (10) | 0.67359 (11) | 0.32481 (10) | 0.0344 (3) | |
O1C | 0.29952 (10) | 0.78374 (10) | 0.06637 (9) | 0.0250 (3) | |
O2C | 0.11212 (10) | 0.78858 (10) | 0.13782 (9) | 0.0260 (3) | |
O3C | 0.20873 (11) | 0.66232 (11) | 0.24296 (10) | 0.0310 (3) | |
O1D | −0.08197 (10) | 0.80541 (10) | 0.42444 (9) | 0.0265 (3) | |
O2D | −0.03700 (9) | 0.81178 (10) | 0.56143 (9) | 0.0251 (3) | |
O3D | 0.02187 (10) | 0.67259 (11) | 0.51314 (10) | 0.0331 (3) | |
C1A | 0.19513 (14) | 0.99115 (14) | 0.42444 (13) | 0.0239 (4) | |
H1A | 0.2222 | 1.0501 | 0.3648 | 0.029* | |
C2A | 0.25267 (14) | 0.95390 (14) | 0.48748 (13) | 0.0233 (4) | |
C3A | 0.21105 (14) | 0.86730 (15) | 0.57387 (13) | 0.0239 (4) | |
C4A | 0.11502 (14) | 0.81716 (14) | 0.60086 (14) | 0.0246 (4) | |
C5A | 0.06242 (14) | 0.85866 (14) | 0.53393 (13) | 0.0235 (4) | |
C6A | 0.09877 (14) | 0.94465 (14) | 0.44598 (13) | 0.0227 (4) | |
C7A | 0.07040 (16) | 0.72542 (16) | 0.69608 (15) | 0.0345 (5) | |
H7A1 | 0.1199 | 0.7067 | 0.7317 | 0.052* | |
H7A2 | 0.0534 | 0.6692 | 0.6853 | 0.052* | |
H7A3 | 0.0088 | 0.7405 | 0.7334 | 0.052* | |
C8A | 0.35871 (14) | 1.00412 (15) | 0.46023 (14) | 0.0253 (4) | |
H8A1 | 0.3721 | 0.9976 | 0.5188 | 0.030* | |
H8A2 | 0.3630 | 1.0771 | 0.4160 | 0.030* | |
C9A | 0.36897 (14) | 0.69707 (15) | 0.74569 (14) | 0.0265 (4) | |
C10A | 0.35124 (16) | 0.59170 (16) | 0.79585 (15) | 0.0338 (5) | |
H10A | 0.3299 | 0.5545 | 0.7686 | 0.041* | |
C11A | 0.36511 (18) | 0.54167 (19) | 0.88606 (16) | 0.0443 (6) | |
H11A | 0.3528 | 0.4700 | 0.9208 | 0.053* | |
C12A | 0.39638 (18) | 0.5952 (2) | 0.92518 (16) | 0.0463 (6) | |
H12A | 0.4063 | 0.5604 | 0.9866 | 0.056* | |
C13A | 0.41351 (19) | 0.6994 (2) | 0.87595 (17) | 0.0473 (6) | |
H13A | 0.4349 | 0.7360 | 0.9037 | 0.057* | |
C14A | 0.39949 (17) | 0.75105 (18) | 0.78587 (15) | 0.0378 (5) | |
H14A | 0.4108 | 0.8228 | 0.7522 | 0.045* | |
C1B | 0.46749 (14) | 0.99163 (14) | 0.31262 (13) | 0.0244 (4) | |
H1B | 0.4392 | 1.0488 | 0.2751 | 0.029* | |
C2B | 0.53674 (14) | 0.94606 (14) | 0.26635 (13) | 0.0241 (4) | |
C3B | 0.57720 (14) | 0.86308 (15) | 0.32371 (14) | 0.0250 (4) | |
C4B | 0.55347 (14) | 0.82460 (15) | 0.42299 (14) | 0.0263 (4) | |
C5B | 0.48240 (14) | 0.87296 (15) | 0.46416 (13) | 0.0246 (4) | |
C6B | 0.43862 (14) | 0.95615 (14) | 0.41178 (13) | 0.0232 (4) | |
C7B | 0.60064 (17) | 0.73656 (17) | 0.48175 (15) | 0.0365 (5) | |
H7B1 | 0.6048 | 0.7425 | 0.5379 | 0.055* | |
H7B2 | 0.6690 | 0.7360 | 0.4425 | 0.055* | |
H7B3 | 0.5590 | 0.6735 | 0.5033 | 0.055* | |
C8B | 0.56298 (15) | 0.98464 (15) | 0.15868 (13) | 0.0267 (4) | |
H8B1 | 0.6338 | 0.9735 | 0.1331 | 0.032* | |
H8B2 | 0.5584 | 1.0583 | 0.1275 | 0.032* | |
C9B | 0.71418 (15) | 0.66821 (16) | 0.23315 (15) | 0.0296 (4) | |
C10B | 0.72732 (17) | 0.58210 (17) | 0.31116 (18) | 0.0373 (5) | |
H10B | 0.6810 | 0.5605 | 0.3739 | 0.045* | |
C11B | 0.80909 (18) | 0.52802 (18) | 0.2962 (2) | 0.0459 (6) | |
H11B | 0.8188 | 0.4697 | 0.3489 | 0.055* | |
C12B | 0.87546 (18) | 0.5590 (2) | 0.2052 (2) | 0.0470 (6) | |
H12B | 0.9313 | 0.5223 | 0.1955 | 0.056* | |
C13B | 0.86170 (18) | 0.6421 (2) | 0.1286 (2) | 0.0497 (7) | |
H13B | 0.9075 | 0.6620 | 0.0659 | 0.060* | |
C14B | 0.78131 (17) | 0.6980 (2) | 0.14123 (17) | 0.0434 (6) | |
H14B | 0.7724 | 0.7560 | 0.0877 | 0.052* | |
C1C | 0.40529 (14) | 0.97320 (14) | 0.11292 (13) | 0.0241 (4) | |
H1C | 0.3904 | 1.0354 | 0.1140 | 0.029* | |
C2C | 0.33983 (14) | 0.92483 (14) | 0.09105 (12) | 0.0227 (4) | |
C3C | 0.36369 (14) | 0.83356 (14) | 0.09052 (13) | 0.0232 (4) | |
C4C | 0.44987 (14) | 0.78914 (15) | 0.10945 (13) | 0.0246 (4) | |
C5C | 0.51171 (14) | 0.84139 (15) | 0.13116 (13) | 0.0241 (4) | |
C6C | 0.49252 (14) | 0.93202 (14) | 0.13327 (13) | 0.0240 (4) | |
C7C | 0.47466 (16) | 0.69088 (16) | 0.10745 (16) | 0.0317 (5) | |
H7C1 | 0.4156 | 0.6587 | 0.1053 | 0.048* | |
H7C2 | 0.4923 | 0.6459 | 0.1655 | 0.048* | |
H7C3 | 0.5322 | 0.7041 | 0.0503 | 0.048* | |
C8C | 0.24356 (14) | 0.96932 (14) | 0.07192 (13) | 0.0241 (4) | |
H8C1 | 0.2544 | 1.0439 | 0.0441 | 0.029* | |
H8C2 | 0.2276 | 0.9529 | 0.0247 | 0.029* | |
C9C | 0.16854 (14) | 0.63680 (15) | 0.09894 (14) | 0.0251 (4) | |
C10C | 0.17014 (16) | 0.53322 (16) | 0.14934 (16) | 0.0331 (5) | |
H10C | 0.1867 | 0.5055 | 0.2078 | 0.040* | |
C11C | 0.14744 (17) | 0.47044 (18) | 0.11403 (19) | 0.0418 (6) | |
H11C | 0.1495 | 0.3996 | 0.1478 | 0.050* | |
C12C | 0.12199 (17) | 0.5105 (2) | 0.0301 (2) | 0.0457 (6) | |
H12C | 0.1054 | 0.4670 | 0.0067 | 0.055* | |
C13C | 0.12048 (19) | 0.6130 (2) | −0.02015 (19) | 0.0462 (6) | |
H13C | 0.1030 | 0.6400 | −0.0781 | 0.055* | |
C14C | 0.14423 (17) | 0.67743 (18) | 0.01321 (16) | 0.0368 (5) | |
H14C | 0.1439 | 0.7484 | −0.0220 | 0.044* | |
C1D | 0.13485 (14) | 0.97464 (14) | 0.22290 (13) | 0.0239 (4) | |
H1D | 0.1751 | 1.0356 | 0.2027 | 0.029* | |
C2D | 0.05730 (14) | 0.93516 (14) | 0.31036 (13) | 0.0231 (4) | |
C3D | −0.00030 (14) | 0.84668 (15) | 0.33686 (13) | 0.0242 (4) | |
C4D | 0.01450 (14) | 0.79593 (15) | 0.28118 (14) | 0.0255 (4) | |
C5D | 0.09407 (14) | 0.83894 (14) | 0.19564 (13) | 0.0232 (4) | |
C6D | 0.15514 (14) | 0.92744 (14) | 0.16438 (13) | 0.0228 (4) | |
C7D | −0.05138 (17) | 0.70142 (17) | 0.31159 (16) | 0.0365 (5) | |
H7D1 | −0.0530 | 0.6961 | 0.2544 | 0.055* | |
H7D2 | −0.1204 | 0.7041 | 0.3481 | 0.055* | |
H7D3 | −0.0237 | 0.6424 | 0.3521 | 0.055* | |
C8D | 0.03903 (14) | 0.98661 (14) | 0.37464 (13) | 0.0235 (4) | |
H8D1 | 0.0594 | 1.0602 | 0.3342 | 0.028* | |
H8D2 | −0.0343 | 0.9763 | 0.4101 | 0.028* | |
C9D | −0.18126 (14) | 0.67358 (15) | 0.60172 (14) | 0.0258 (4) | |
C10D | −0.21742 (16) | 0.59045 (16) | 0.59617 (15) | 0.0319 (5) | |
H10D | −0.1763 | 0.5680 | 0.5530 | 0.038* | |
C11D | −0.31361 (16) | 0.54133 (16) | 0.65406 (16) | 0.0367 (5) | |
H11D | −0.3388 | 0.4852 | 0.6505 | 0.044* | |
C12D | −0.37320 (16) | 0.57426 (17) | 0.71741 (16) | 0.0386 (5) | |
H12D | −0.4393 | 0.5406 | 0.7567 | 0.046* | |
C13D | −0.33707 (16) | 0.65558 (18) | 0.72374 (16) | 0.0388 (5) | |
H13D | −0.3781 | 0.6770 | 0.7678 | 0.047* | |
C14D | −0.24110 (16) | 0.70591 (16) | 0.66583 (15) | 0.0321 (5) | |
H14D | −0.2163 | 0.7620 | 0.6698 | 0.039* |
U11 | U22 | U33 | U12 | U13 | U23 | |
N1 | 0.026 (2) | 0.068 (3) | 0.030 (2) | 0.002 (2) | −0.0062 (16) | −0.031 (2) |
O1 | 0.0231 (15) | 0.0457 (19) | 0.0267 (16) | −0.0007 (14) | −0.0038 (12) | −0.0216 (15) |
N2 | 0.025 (2) | 0.084 (4) | 0.036 (3) | 0.012 (2) | −0.0103 (18) | −0.041 (3) |
O2 | 0.0266 (16) | 0.0343 (17) | 0.0239 (16) | 0.0087 (14) | −0.0083 (12) | −0.0176 (15) |
B1 | 0.0572 (18) | 0.0266 (13) | 0.0331 (14) | 0.0055 (12) | −0.0109 (13) | −0.0106 (11) |
F1 | 0.1356 (18) | 0.0472 (10) | 0.0887 (13) | 0.0254 (11) | −0.0712 (13) | −0.0180 (10) |
F2 | 0.0914 (12) | 0.0594 (10) | 0.0434 (9) | −0.0021 (9) | −0.0133 (8) | −0.0296 (8) |
F3 | 0.0762 (11) | 0.0290 (7) | 0.0436 (8) | −0.0007 (7) | −0.0064 (7) | −0.0092 (6) |
F4 | 0.0738 (12) | 0.0646 (11) | 0.0825 (13) | −0.0121 (9) | 0.0162 (10) | −0.0432 (10) |
P1A | 0.0246 (3) | 0.0281 (3) | 0.0190 (2) | −0.0001 (2) | −0.0069 (2) | −0.0100 (2) |
P1B | 0.0213 (2) | 0.0333 (3) | 0.0237 (3) | 0.0047 (2) | −0.0060 (2) | −0.0135 (2) |
P1C | 0.0246 (3) | 0.0281 (3) | 0.0211 (2) | 0.0035 (2) | −0.0079 (2) | −0.0136 (2) |
P1D | 0.0200 (2) | 0.0283 (3) | 0.0246 (3) | 0.00258 (19) | −0.0042 (2) | −0.0137 (2) |
O1A | 0.0255 (7) | 0.0335 (8) | 0.0207 (7) | 0.0036 (6) | −0.0088 (6) | −0.0119 (6) |
O2A | 0.0254 (7) | 0.0322 (7) | 0.0175 (6) | −0.0013 (6) | −0.0063 (5) | −0.0100 (6) |
O3A | 0.0361 (8) | 0.0342 (8) | 0.0264 (7) | −0.0018 (6) | −0.0103 (6) | −0.0151 (6) |
O1B | 0.0234 (7) | 0.0387 (8) | 0.0259 (7) | 0.0058 (6) | −0.0076 (6) | −0.0170 (6) |
O2B | 0.0219 (7) | 0.0378 (8) | 0.0237 (7) | 0.0060 (6) | −0.0073 (6) | −0.0150 (6) |
O3B | 0.0269 (8) | 0.0400 (9) | 0.0297 (8) | 0.0012 (6) | −0.0030 (6) | −0.0139 (7) |
O1C | 0.0237 (7) | 0.0313 (7) | 0.0241 (7) | 0.0020 (6) | −0.0074 (5) | −0.0161 (6) |
O2C | 0.0258 (7) | 0.0333 (7) | 0.0261 (7) | 0.0062 (6) | −0.0090 (6) | −0.0193 (6) |
O3C | 0.0372 (8) | 0.0351 (8) | 0.0227 (7) | 0.0052 (6) | −0.0116 (6) | −0.0136 (6) |
O1D | 0.0211 (7) | 0.0349 (8) | 0.0232 (7) | 0.0012 (6) | −0.0036 (5) | −0.0149 (6) |
O2D | 0.0198 (6) | 0.0314 (7) | 0.0241 (7) | 0.0003 (5) | −0.0042 (5) | −0.0143 (6) |
O3D | 0.0259 (7) | 0.0353 (8) | 0.0372 (8) | 0.0081 (6) | −0.0053 (6) | −0.0190 (7) |
C1A | 0.0292 (10) | 0.0212 (9) | 0.0206 (9) | 0.0029 (8) | −0.0048 (8) | −0.0107 (8) |
C2A | 0.0234 (9) | 0.0245 (10) | 0.0243 (10) | 0.0027 (7) | −0.0053 (8) | −0.0143 (8) |
C3A | 0.0238 (10) | 0.0295 (10) | 0.0215 (9) | 0.0051 (8) | −0.0089 (8) | −0.0133 (8) |
C4A | 0.0227 (9) | 0.0280 (10) | 0.0220 (9) | 0.0019 (8) | −0.0044 (8) | −0.0121 (8) |
C5A | 0.0190 (9) | 0.0285 (10) | 0.0245 (10) | 0.0017 (7) | −0.0038 (7) | −0.0152 (8) |
C6A | 0.0260 (10) | 0.0237 (9) | 0.0234 (9) | 0.0071 (8) | −0.0084 (8) | −0.0150 (8) |
C7A | 0.0294 (11) | 0.0365 (12) | 0.0269 (11) | −0.0024 (9) | −0.0079 (9) | −0.0058 (9) |
C8A | 0.0268 (10) | 0.0260 (10) | 0.0242 (10) | −0.0005 (8) | −0.0072 (8) | −0.0127 (8) |
C9A | 0.0207 (9) | 0.0348 (11) | 0.0206 (9) | 0.0016 (8) | −0.0049 (8) | −0.0107 (8) |
C10A | 0.0332 (11) | 0.0338 (11) | 0.0283 (11) | 0.0051 (9) | −0.0065 (9) | −0.0112 (9) |
C11A | 0.0400 (13) | 0.0418 (13) | 0.0295 (12) | 0.0120 (11) | −0.0036 (10) | −0.0030 (10) |
C12A | 0.0374 (13) | 0.0701 (18) | 0.0227 (11) | 0.0156 (12) | −0.0118 (10) | −0.0132 (12) |
C13A | 0.0482 (15) | 0.0689 (18) | 0.0307 (12) | 0.0020 (13) | −0.0183 (11) | −0.0237 (13) |
C14A | 0.0420 (13) | 0.0430 (13) | 0.0264 (11) | −0.0031 (10) | −0.0121 (10) | −0.0129 (10) |
C1B | 0.0251 (10) | 0.0230 (9) | 0.0226 (9) | −0.0024 (7) | −0.0081 (8) | −0.0075 (8) |
C2B | 0.0227 (9) | 0.0259 (10) | 0.0211 (9) | −0.0051 (7) | −0.0048 (8) | −0.0092 (8) |
C3B | 0.0194 (9) | 0.0331 (11) | 0.0229 (10) | 0.0016 (8) | −0.0048 (8) | −0.0142 (8) |
C4B | 0.0234 (10) | 0.0331 (11) | 0.0243 (10) | 0.0020 (8) | −0.0095 (8) | −0.0134 (9) |
C5B | 0.0239 (9) | 0.0310 (10) | 0.0171 (9) | −0.0041 (8) | −0.0050 (7) | −0.0100 (8) |
C6B | 0.0214 (9) | 0.0242 (10) | 0.0235 (9) | −0.0032 (7) | −0.0063 (8) | −0.0106 (8) |
C7B | 0.0389 (12) | 0.0436 (13) | 0.0253 (11) | 0.0145 (10) | −0.0136 (9) | −0.0128 (10) |
C8B | 0.0277 (10) | 0.0282 (10) | 0.0194 (9) | −0.0032 (8) | −0.0052 (8) | −0.0079 (8) |
C9B | 0.0232 (10) | 0.0376 (11) | 0.0345 (11) | 0.0060 (8) | −0.0112 (9) | −0.0207 (10) |
C10B | 0.0312 (11) | 0.0327 (12) | 0.0453 (13) | 0.0029 (9) | −0.0123 (10) | −0.0155 (10) |
C11B | 0.0396 (13) | 0.0287 (12) | 0.0712 (18) | 0.0076 (10) | −0.0239 (13) | −0.0206 (12) |
C12B | 0.0305 (12) | 0.0490 (15) | 0.081 (2) | 0.0129 (11) | −0.0206 (13) | −0.0453 (15) |
C13B | 0.0350 (13) | 0.0731 (19) | 0.0529 (16) | 0.0167 (13) | −0.0103 (12) | −0.0414 (15) |
C14B | 0.0358 (13) | 0.0615 (16) | 0.0351 (12) | 0.0169 (11) | −0.0117 (10) | −0.0243 (12) |
C1C | 0.0290 (10) | 0.0238 (9) | 0.0155 (9) | 0.0007 (8) | −0.0039 (8) | −0.0074 (7) |
C2C | 0.0221 (9) | 0.0264 (10) | 0.0136 (8) | 0.0009 (7) | −0.0020 (7) | −0.0064 (7) |
C3C | 0.0231 (9) | 0.0285 (10) | 0.0174 (9) | −0.0005 (8) | −0.0053 (7) | −0.0104 (8) |
C4C | 0.0244 (10) | 0.0279 (10) | 0.0185 (9) | 0.0014 (8) | −0.0032 (7) | −0.0102 (8) |
C5C | 0.0200 (9) | 0.0311 (10) | 0.0178 (9) | 0.0029 (8) | −0.0045 (7) | −0.0091 (8) |
C6C | 0.0254 (10) | 0.0269 (10) | 0.0140 (8) | −0.0035 (8) | −0.0029 (7) | −0.0061 (8) |
C7C | 0.0295 (11) | 0.0348 (11) | 0.0355 (11) | 0.0076 (9) | −0.0103 (9) | −0.0201 (10) |
C8C | 0.0261 (10) | 0.0251 (10) | 0.0188 (9) | 0.0033 (8) | −0.0062 (8) | −0.0086 (8) |
C9C | 0.0220 (9) | 0.0308 (10) | 0.0269 (10) | 0.0032 (8) | −0.0063 (8) | −0.0179 (9) |
C10C | 0.0302 (11) | 0.0330 (11) | 0.0360 (12) | 0.0052 (9) | −0.0082 (9) | −0.0172 (10) |
C11C | 0.0346 (12) | 0.0349 (12) | 0.0553 (15) | 0.0012 (10) | −0.0030 (11) | −0.0266 (12) |
C12C | 0.0331 (12) | 0.0603 (17) | 0.0659 (17) | 0.0036 (11) | −0.0112 (12) | −0.0499 (15) |
C13C | 0.0460 (14) | 0.0673 (18) | 0.0474 (14) | 0.0100 (12) | −0.0237 (12) | −0.0396 (14) |
C14C | 0.0420 (13) | 0.0415 (13) | 0.0356 (12) | 0.0095 (10) | −0.0180 (10) | −0.0218 (10) |
C1D | 0.0249 (10) | 0.0225 (9) | 0.0236 (10) | 0.0046 (7) | −0.0092 (8) | −0.0092 (8) |
C2D | 0.0243 (9) | 0.0256 (10) | 0.0231 (9) | 0.0078 (8) | −0.0102 (8) | −0.0129 (8) |
C3D | 0.0200 (9) | 0.0319 (10) | 0.0204 (9) | 0.0037 (8) | −0.0050 (7) | −0.0125 (8) |
C4D | 0.0227 (9) | 0.0314 (10) | 0.0262 (10) | 0.0034 (8) | −0.0081 (8) | −0.0161 (9) |
C5D | 0.0235 (9) | 0.0302 (10) | 0.0229 (9) | 0.0078 (8) | −0.0093 (8) | −0.0171 (8) |
C6D | 0.0227 (9) | 0.0258 (10) | 0.0201 (9) | 0.0067 (7) | −0.0089 (7) | −0.0096 (8) |
C7D | 0.0336 (12) | 0.0433 (13) | 0.0365 (12) | −0.0068 (10) | −0.0026 (10) | −0.0258 (11) |
C8D | 0.0250 (10) | 0.0243 (9) | 0.0232 (9) | 0.0067 (8) | −0.0077 (8) | −0.0126 (8) |
C9D | 0.0212 (9) | 0.0282 (10) | 0.0238 (10) | 0.0027 (8) | −0.0066 (8) | −0.0088 (8) |
C10D | 0.0305 (11) | 0.0316 (11) | 0.0324 (11) | 0.0034 (9) | −0.0093 (9) | −0.0139 (9) |
C11D | 0.0326 (12) | 0.0286 (11) | 0.0417 (13) | −0.0010 (9) | −0.0120 (10) | −0.0095 (10) |
C12D | 0.0242 (11) | 0.0371 (12) | 0.0360 (12) | 0.0006 (9) | −0.0053 (9) | −0.0035 (10) |
C13D | 0.0289 (11) | 0.0463 (14) | 0.0326 (12) | 0.0053 (10) | −0.0007 (9) | −0.0165 (11) |
C14D | 0.0289 (11) | 0.0363 (12) | 0.0296 (11) | 0.0034 (9) | −0.0048 (9) | −0.0163 (9) |
N1—O1 | 0.966 (5) | C7B—H7B2 | 0.9800 |
N2—O2 | 0.885 (5) | C7B—H7B3 | 0.9800 |
B1—F3 | 1.374 (3) | C8B—C6C | 1.524 (3) |
B1—F2 | 1.379 (3) | C8B—H8B1 | 0.9900 |
B1—F1 | 1.382 (3) | C8B—H8B2 | 0.9900 |
B1—F4 | 1.387 (3) | C9B—C14B | 1.392 (3) |
P1A—O3A | 1.4716 (14) | C9B—C10B | 1.397 (3) |
P1A—O1A | 1.5894 (14) | C10B—C11B | 1.397 (3) |
P1A—O2A | 1.5950 (14) | C10B—H10B | 0.9500 |
P1A—C9A | 1.768 (2) | C11B—C12B | 1.374 (4) |
P1B—O3B | 1.4688 (15) | C11B—H11B | 0.9500 |
P1B—O2B | 1.5825 (14) | C12B—C13B | 1.366 (4) |
P1B—O1B | 1.5943 (15) | C12B—H12B | 0.9500 |
P1B—C9B | 1.776 (2) | C13B—C14B | 1.392 (3) |
P1C—O3C | 1.4695 (14) | C13B—H13B | 0.9500 |
P1C—O1C | 1.5911 (14) | C14B—H14B | 0.9500 |
P1C—O2C | 1.5921 (14) | C1C—C2C | 1.391 (3) |
P1C—C9C | 1.7727 (19) | C1C—C6C | 1.396 (3) |
P1D—O3D | 1.4738 (14) | C1C—H1C | 0.9500 |
P1D—O2D | 1.5867 (14) | C2C—C3C | 1.393 (3) |
P1D—O1D | 1.5916 (14) | C2C—C8C | 1.521 (3) |
P1D—C9D | 1.7708 (19) | C3C—C4C | 1.392 (3) |
O1A—C3A | 1.420 (2) | C4C—C5C | 1.392 (3) |
O2A—C5B | 1.418 (2) | C4C—C7C | 1.506 (3) |
O1B—C3B | 1.425 (2) | C5C—C6C | 1.382 (3) |
O2B—C5C | 1.412 (2) | C7C—H7C1 | 0.9800 |
O1C—C3C | 1.418 (2) | C7C—H7C2 | 0.9800 |
O2C—C5D | 1.418 (2) | C7C—H7C3 | 0.9800 |
O1D—C3D | 1.422 (2) | C8C—C6D | 1.518 (3) |
O2D—C5A | 1.418 (2) | C8C—H8C1 | 0.9900 |
C1A—C2A | 1.392 (3) | C8C—H8C2 | 0.9900 |
C1A—C6A | 1.399 (3) | C9C—C10C | 1.388 (3) |
C1A—H1A | 0.9500 | C9C—C14C | 1.394 (3) |
C2A—C3A | 1.389 (3) | C10C—C11C | 1.386 (3) |
C2A—C8A | 1.520 (3) | C10C—H10C | 0.9500 |
C3A—C4A | 1.397 (3) | C11C—C12C | 1.377 (4) |
C4A—C5A | 1.391 (3) | C11C—H11C | 0.9500 |
C4A—C7A | 1.502 (3) | C12C—C13C | 1.374 (4) |
C5A—C6A | 1.388 (3) | C12C—H12C | 0.9500 |
C6A—C8D | 1.519 (3) | C13C—C14C | 1.387 (3) |
C7A—H7A1 | 0.9800 | C13C—H13C | 0.9500 |
C7A—H7A2 | 0.9800 | C14C—H14C | 0.9500 |
C7A—H7A3 | 0.9800 | C1D—C6D | 1.389 (3) |
C8A—C6B | 1.521 (3) | C1D—C2D | 1.393 (3) |
C8A—H8A1 | 0.9900 | C1D—H1D | 0.9500 |
C8A—H8A2 | 0.9900 | C2D—C3D | 1.385 (3) |
C9A—C14A | 1.385 (3) | C2D—C8D | 1.522 (3) |
C9A—C10A | 1.396 (3) | C3D—C4D | 1.395 (3) |
C10A—C11A | 1.391 (3) | C4D—C5D | 1.389 (3) |
C10A—H10A | 0.9500 | C4D—C7D | 1.502 (3) |
C11A—C12A | 1.370 (4) | C5D—C6D | 1.391 (3) |
C11A—H11A | 0.9500 | C7D—H7D1 | 0.9800 |
C12A—C13A | 1.380 (4) | C7D—H7D2 | 0.9800 |
C12A—H12A | 0.9500 | C7D—H7D3 | 0.9800 |
C13A—C14A | 1.391 (3) | C8D—H8D1 | 0.9900 |
C13A—H13A | 0.9500 | C8D—H8D2 | 0.9900 |
C14A—H14A | 0.9500 | C9D—C14D | 1.394 (3) |
C1B—C6B | 1.391 (3) | C9D—C10D | 1.402 (3) |
C1B—C2B | 1.398 (3) | C10D—C11D | 1.385 (3) |
C1B—H1B | 0.9500 | C10D—H10D | 0.9500 |
C2B—C3B | 1.392 (3) | C11D—C12D | 1.390 (3) |
C2B—C8B | 1.515 (3) | C11D—H11D | 0.9500 |
C3B—C4B | 1.392 (3) | C12D—C13D | 1.384 (3) |
C4B—C5B | 1.396 (3) | C12D—H12D | 0.9500 |
C4B—C7B | 1.498 (3) | C13D—C14D | 1.387 (3) |
C5B—C6B | 1.391 (3) | C13D—H13D | 0.9500 |
C7B—H7B1 | 0.9800 | C14D—H14D | 0.9500 |
F3—B1—F2 | 111.3 (2) | H8B1—C8B—H8B2 | 107.9 |
F3—B1—F1 | 109.5 (2) | C14B—C9B—C10B | 119.8 (2) |
F2—B1—F1 | 108.9 (2) | C14B—C9B—P1B | 121.19 (17) |
F3—B1—F4 | 110.4 (2) | C10B—C9B—P1B | 118.96 (16) |
F2—B1—F4 | 110.1 (2) | C11B—C10B—C9B | 119.5 (2) |
F1—B1—F4 | 106.6 (2) | C11B—C10B—H10B | 120.3 |
O3A—P1A—O1A | 113.25 (8) | C9B—C10B—H10B | 120.3 |
O3A—P1A—O2A | 113.39 (8) | C12B—C11B—C10B | 120.1 (2) |
O1A—P1A—O2A | 105.21 (7) | C12B—C11B—H11B | 119.9 |
O3A—P1A—C9A | 116.42 (9) | C10B—C11B—H11B | 119.9 |
O1A—P1A—C9A | 103.86 (8) | C13B—C12B—C11B | 120.5 (2) |
O2A—P1A—C9A | 103.48 (8) | C13B—C12B—H12B | 119.7 |
O3B—P1B—O2B | 114.65 (8) | C11B—C12B—H12B | 119.7 |
O3B—P1B—O1B | 112.61 (8) | C12B—C13B—C14B | 120.8 (2) |
O2B—P1B—O1B | 105.36 (8) | C12B—C13B—H13B | 119.6 |
O3B—P1B—C9B | 116.20 (10) | C14B—C13B—H13B | 119.6 |
O2B—P1B—C9B | 102.10 (9) | C9B—C14B—C13B | 119.3 (2) |
O1B—P1B—C9B | 104.63 (8) | C9B—C14B—H14B | 120.3 |
O3C—P1C—O1C | 113.22 (8) | C13B—C14B—H14B | 120.3 |
O3C—P1C—O2C | 113.28 (8) | C2C—C1C—C6C | 121.17 (18) |
O1C—P1C—O2C | 105.45 (7) | C2C—C1C—H1C | 119.4 |
O3C—P1C—C9C | 116.01 (9) | C6C—C1C—H1C | 119.4 |
O1C—P1C—C9C | 103.90 (8) | C1C—C2C—C3C | 117.94 (17) |
O2C—P1C—C9C | 103.83 (8) | C1C—C2C—C8C | 120.41 (17) |
O3D—P1D—O2D | 113.92 (8) | C3C—C2C—C8C | 121.62 (17) |
O3D—P1D—O1D | 112.87 (8) | C4C—C3C—C2C | 123.55 (17) |
O2D—P1D—O1D | 105.77 (7) | C4C—C3C—O1C | 117.27 (16) |
O3D—P1D—C9D | 116.93 (9) | C2C—C3C—O1C | 119.14 (16) |
O2D—P1D—C9D | 103.46 (8) | C5C—C4C—C3C | 115.43 (17) |
O1D—P1D—C9D | 102.56 (8) | C5C—C4C—C7C | 121.96 (18) |
C3A—O1A—P1A | 120.78 (12) | C3C—C4C—C7C | 122.60 (18) |
C5B—O2A—P1A | 118.31 (11) | C6C—C5C—C4C | 124.08 (18) |
C3B—O1B—P1B | 119.32 (12) | C6C—C5C—O2B | 118.99 (17) |
C5C—O2B—P1B | 121.91 (11) | C4C—C5C—O2B | 116.88 (17) |
C3C—O1C—P1C | 120.00 (11) | C5C—C6C—C1C | 117.82 (17) |
C5D—O2C—P1C | 118.16 (11) | C5C—C6C—C8B | 121.32 (18) |
C3D—O1D—P1D | 119.51 (12) | C1C—C6C—C8B | 120.85 (17) |
C5A—O2D—P1D | 121.38 (11) | C4C—C7C—H7C1 | 109.5 |
C2A—C1A—C6A | 122.21 (17) | C4C—C7C—H7C2 | 109.5 |
C2A—C1A—H1A | 118.9 | H7C1—C7C—H7C2 | 109.5 |
C6A—C1A—H1A | 118.9 | C4C—C7C—H7C3 | 109.5 |
C3A—C2A—C1A | 117.45 (17) | H7C1—C7C—H7C3 | 109.5 |
C3A—C2A—C8A | 121.68 (17) | H7C2—C7C—H7C3 | 109.5 |
C1A—C2A—C8A | 120.82 (17) | C6D—C8C—C2C | 110.63 (15) |
C2A—C3A—C4A | 123.67 (18) | C6D—C8C—H8C1 | 109.5 |
C2A—C3A—O1A | 118.98 (16) | C2C—C8C—H8C1 | 109.5 |
C4A—C3A—O1A | 117.30 (16) | C6D—C8C—H8C2 | 109.5 |
C5A—C4A—C3A | 115.46 (17) | C2C—C8C—H8C2 | 109.5 |
C5A—C4A—C7A | 121.91 (17) | H8C1—C8C—H8C2 | 108.1 |
C3A—C4A—C7A | 122.63 (18) | C10C—C9C—C14C | 120.11 (19) |
C6A—C5A—C4A | 124.41 (17) | C10C—C9C—P1C | 118.53 (16) |
C6A—C5A—O2D | 118.99 (17) | C14C—C9C—P1C | 121.36 (16) |
C4A—C5A—O2D | 116.51 (16) | C11C—C10C—C9C | 119.7 (2) |
C5A—C6A—C1A | 116.79 (17) | C11C—C10C—H10C | 120.2 |
C5A—C6A—C8D | 122.56 (17) | C9C—C10C—H10C | 120.2 |
C1A—C6A—C8D | 120.65 (17) | C12C—C11C—C10C | 120.1 (2) |
C4A—C7A—H7A1 | 109.5 | C12C—C11C—H11C | 119.9 |
C4A—C7A—H7A2 | 109.5 | C10C—C11C—H11C | 119.9 |
H7A1—C7A—H7A2 | 109.5 | C13C—C12C—C11C | 120.4 (2) |
C4A—C7A—H7A3 | 109.5 | C13C—C12C—H12C | 119.8 |
H7A1—C7A—H7A3 | 109.5 | C11C—C12C—H12C | 119.8 |
H7A2—C7A—H7A3 | 109.5 | C12C—C13C—C14C | 120.5 (2) |
C2A—C8A—C6B | 111.10 (15) | C12C—C13C—H13C | 119.8 |
C2A—C8A—H8A1 | 109.4 | C14C—C13C—H13C | 119.8 |
C6B—C8A—H8A1 | 109.4 | C13C—C14C—C9C | 119.2 (2) |
C2A—C8A—H8A2 | 109.4 | C13C—C14C—H14C | 120.4 |
C6B—C8A—H8A2 | 109.4 | C9C—C14C—H14C | 120.4 |
H8A1—C8A—H8A2 | 108.0 | C6D—C1D—C2D | 121.92 (18) |
C14A—C9A—C10A | 120.16 (19) | C6D—C1D—H1D | 119.0 |
C14A—C9A—P1A | 121.45 (16) | C2D—C1D—H1D | 119.0 |
C10A—C9A—P1A | 118.38 (16) | C3D—C2D—C1D | 117.33 (17) |
C11A—C10A—C9A | 119.4 (2) | C3D—C2D—C8D | 121.87 (17) |
C11A—C10A—H10A | 120.3 | C1D—C2D—C8D | 120.79 (17) |
C9A—C10A—H10A | 120.3 | C2D—C3D—C4D | 124.00 (17) |
C12A—C11A—C10A | 120.4 (2) | C2D—C3D—O1D | 119.04 (16) |
C12A—C11A—H11A | 119.8 | C4D—C3D—O1D | 116.93 (17) |
C10A—C11A—H11A | 119.8 | C5D—C4D—C3D | 115.41 (17) |
C11A—C12A—C13A | 120.4 (2) | C5D—C4D—C7D | 122.33 (17) |
C11A—C12A—H12A | 119.8 | C3D—C4D—C7D | 122.26 (18) |
C13A—C12A—H12A | 119.8 | C4D—C5D—C6D | 123.81 (17) |
C12A—C13A—C14A | 120.2 (2) | C4D—C5D—O2C | 116.92 (16) |
C12A—C13A—H13A | 119.9 | C6D—C5D—O2C | 119.27 (16) |
C14A—C13A—H13A | 119.9 | C1D—C6D—C5D | 117.52 (17) |
C9A—C14A—C13A | 119.5 (2) | C1D—C6D—C8C | 120.72 (17) |
C9A—C14A—H14A | 120.3 | C5D—C6D—C8C | 121.72 (17) |
C13A—C14A—H14A | 120.3 | C4D—C7D—H7D1 | 109.5 |
C6B—C1B—C2B | 122.22 (18) | C4D—C7D—H7D2 | 109.5 |
C6B—C1B—H1B | 118.9 | H7D1—C7D—H7D2 | 109.5 |
C2B—C1B—H1B | 118.9 | C4D—C7D—H7D3 | 109.5 |
C3B—C2B—C1B | 117.18 (17) | H7D1—C7D—H7D3 | 109.5 |
C3B—C2B—C8B | 122.31 (18) | H7D2—C7D—H7D3 | 109.5 |
C1B—C2B—C8B | 120.48 (18) | C6A—C8D—C2D | 111.24 (15) |
C4B—C3B—C2B | 123.83 (18) | C6A—C8D—H8D1 | 109.4 |
C4B—C3B—O1B | 116.91 (17) | C2D—C8D—H8D1 | 109.4 |
C2B—C3B—O1B | 119.24 (16) | C6A—C8D—H8D2 | 109.4 |
C3B—C4B—C5B | 115.61 (18) | C2D—C8D—H8D2 | 109.4 |
C3B—C4B—C7B | 122.11 (18) | H8D1—C8D—H8D2 | 108.0 |
C5B—C4B—C7B | 122.28 (18) | C14D—C9D—C10D | 120.33 (18) |
C6B—C5B—C4B | 123.92 (17) | C14D—C9D—P1D | 121.92 (16) |
C6B—C5B—O2A | 119.10 (17) | C10D—C9D—P1D | 117.74 (15) |
C4B—C5B—O2A | 116.97 (17) | C11D—C10D—C9D | 119.5 (2) |
C5B—C6B—C1B | 117.21 (18) | C11D—C10D—H10D | 120.3 |
C5B—C6B—C8A | 122.02 (17) | C9D—C10D—H10D | 120.3 |
C1B—C6B—C8A | 120.71 (17) | C10D—C11D—C12D | 119.9 (2) |
C4B—C7B—H7B1 | 109.5 | C10D—C11D—H11D | 120.0 |
C4B—C7B—H7B2 | 109.5 | C12D—C11D—H11D | 120.0 |
H7B1—C7B—H7B2 | 109.5 | C13D—C12D—C11D | 120.6 (2) |
C4B—C7B—H7B3 | 109.5 | C13D—C12D—H12D | 119.7 |
H7B1—C7B—H7B3 | 109.5 | C11D—C12D—H12D | 119.7 |
H7B2—C7B—H7B3 | 109.5 | C12D—C13D—C14D | 120.1 (2) |
C2B—C8B—C6C | 112.07 (15) | C12D—C13D—H13D | 119.9 |
C2B—C8B—H8B1 | 109.2 | C14D—C13D—H13D | 119.9 |
C6C—C8B—H8B1 | 109.2 | C13D—C14D—C9D | 119.5 (2) |
C2B—C8B—H8B2 | 109.2 | C13D—C14D—H14D | 120.2 |
C6C—C8B—H8B2 | 109.2 | C9D—C14D—H14D | 120.2 |
Cg1, Cg2 and Cg3 are the centroids of the aromatic rings C9B–C14B, C9D–C14D and C1A–C6A, respectively. |
D—H···A | D—H | H···A | D···A | D—H···A |
C1Bi—H1Bi···F1 | 0.95 | 2.41 | 3.344 (3) | 169 |
C14Bii—H14Bii···F2 | 0.95 | 2.57 | 3.357 (3) | 140 |
C7Cii—H7C3ii···F2 | 0.98 | 2.62 | 3.484 (2) | 147 |
C8Ci—H8C1i···F2 | 0.98 | 2.49 | 3.379 (3) | 150 |
C1Di—H1Di···F2 | 0.95 | 2.60 | 3.439 (2) | 147 |
C11Aiii—H11Aiii···F3 | 0.95 | 2.45 | 3.254 (2) | 142 |
C7Cii—H7C3ii···F3 | 0.98 | 2.64 | 3.569 (3) | 160 |
C11C—H11C···F4 | 0.95 | 2.53 | 3.447 (3) | 162 |
C1Di—H1Di···F4 | 0.95 | 2.65 | 3.509 (3) | 150 |
C14Div—H14Div···F4 | 0.95 | 2.63 | 3.336 (4) | 131 |
C7D—H7D1···Cg1v | 0.98 | 2.80 | 3.524 (4) | 131 |
C7B—H7B1···Cg2vi | 0.98 | 2.88 | 3.530 (4) | 124 |
C8D—H8D2···Cg3vii | 0.98 | 2.87 | 3.594 (3) | 131 |
Symmetry codes: (i) x, y−1, z; (ii) −x+1, −y+1, −z; (iii) x, y, z−1; (iv) −x, −y+1, −z+1; (v) x−1, y, z; (vi) x+1, y, z; (vii) −x, −y+2, −z+1. |
O3A···O1 | 2.621 (5) | O3D···O2 | 2.604 (4) |
O3A···N1 | 2.661 (6) | O3D···N2 | 2.650 (4) |
O3B···O1 | 2.609 (3) | O1···PL | 0.471 (4) |
O3B···N1 | 2.664 (5) | N1···PL | 0.492 (6) |
O3C···O2 | 2.621 (4) | O2···PL | 0.466 (4) |
O3C···N2 | 2.625 (7) | N2···PL | 0.416 (6) |
PL is the mean plane passing through the four phosphonate oxygen atoms, O3A, O3B, O3C and O3D. |
Acknowledgements
The Centro Interfacoltà di Misure "G. Casnati" and the "Laboratorio di Strutturistica Mario Nardelli" of the University of Parma are kindly acknowledged for the use of NMR facilities and of the Diffractometer.
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