Tetra­piperidinium di-μ-methoxy-di-μ5-oxo-tetra-μ3-oxo-dodeca-μ2-oxo-octa­oxodeca­vanadate

Sun, F.; Li, Y.-T.; Wu, Z.-Y.; Wang, D.-Q.; Dou, J.-M.

doi:10.1107/S0108270105042241

Tetrapiperidinium di-μ-methoxy-di-μ₅-oxo-tetra-μ₃-oxo-dodeca-μ₂-oxo-octaoxodecavanadate

F. Sun, Y.-T. Li, Z.-Y. Wu, D.-Q. Wang and J.-M. Dou

The structure of the title compound, (C₅H₁₂N)₄[V₁₀O₂₆(CH₃O)₂], reveals the presence of four protonated piperidinium cations and a [{V₁₀O₂₆}(OCH₃)₂]⁴⁻ polyanion having an embedded centre of inversion. The compound is distinguished by presenting, in contrast with other anionic decavanadates, two methoxy groups bridging the outermost V atoms, and it becomes the first example of this type among reported decavanadates.

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Supporting information

	Crystallographic Information File (CIF) https://doi.org/10.1107/S0108270105042241/bg1023sup1.cif Contains datablocks global, I
	Structure factor file (CIF format) https://doi.org/10.1107/S0108270105042241/bg1023Isup2.hkl Contains datablock I

CCDC reference: 299623

Comment top

Polyoxometallates have received increasing attention in recent years, since they have been used successfully as drugs with antiviral activity, for example against herpes or HIV (Rhule et al., 1998). In many other fields, such as catalysis, biology and materials science, the possible applications of polyoxometallates also attract much attention (Müller et al., 1998; Oyaizu & Tsuchida, 1998; Pope & Müller, 1991). In particular, the polyoxovanadate clusters, an important class of polyoxometallates, have been studied extensively because of their fascinating structure and potential applications (Zhang & Chen, 2003). Recently, some interesting studies have been carried out to investigate the interactions of polyoxovanadate with organic ligands (Khan et al., 1993, 1992). Taking into account the above facts, the synthesis of new polyoxovanadates is of considerable interest in order to gain insight into the nature of this kind of complex. In this paper, the title new decavanadate compound with the piperidinium cation, formulated as [(C₅H₁₂N)₄][V₁₀O₂₆(OCH₃)₂], (I), has been synthesized and characterized by single-crystal X-ray diffraction and the results are presented here.

Compound (I) contains a [V₁₀O₂₆(OCH₃)₂]⁴⁻ polyanion and four protonated piperidinium cations. As shown in Fig. 1, its structure consists of a centrosymmetric framework of ten V atoms disposed as two almost regular V₆ octahedra with a common edge, V5—V5ⁱ [symmetry code: (i) −x + 1, −y, −z + 1], the V···V distances ranging from 3.0169 (9) (V1—V5) to 3.2730 (12) Å (V5—V5ⁱ). Each V atom coordinates to six O atoms to form ten small VO₆ octahedra occupying the framework vertexes. The ten V atoms can be distinguished into three categories, namely V_a = atoms V5 and V5ⁱ, V_b = atoms V2, V4, V2ⁱ and V4ⁱ, and V_c = atoms V1, V3, V1ⁱ and V3ⁱ. V_a atoms form the common edge, as mentioned above, V_b atoms form two tetrahedra and V_c atoms form quadrangles with V_a atoms. In the polyanion, four different modes for bonding of the oxo ligands are present. Eight terminal O atoms, O1–O4 and O1ⁱ–O4ⁱ, are simply η¹-bonded to V_b and V_c atoms, with short V—O distances from 1.598 (2) (V2—O2) to 1.603 (2) Å (V4—O4), which indicate substantial V═O character (Table 1). Atoms O5, O5ⁱ, O7–O11 and O7ⁱ–O11ⁱ are µ₂-bonded to the corresponding V—V edges of the framework. Two short distances [V5—O5 = 1.689 (2) Å and V5—O9 = 1.684 (2) Å] are observed and result in the two long V—O distances V1—O9 [2.033 (2) Å] and V3ⁱ—O5 [2.033 (2) Å]. For other µ₂-bridging oxo ligands, the V—O distances are in the range 1.755 (2)–1.904 (2) Å (V2—O10 and V3—O10, respectively). Atoms O12, O13, O12ⁱ and O13ⁱ are µ₃-bridging O atoms which form similar V—O interactions in the range 1.903 (2)–2.051 (2) Å (V5—O13 and V2—O13). Finally, both atoms O14 and O14ⁱ are in the centre of a V₆ octahedron and coordinate to six V atoms with long V—O distances, ranging from 2.072 (2) (V5—O14) to 2.337 (2) Å (V3—O14), which obviously correlate with the short V—O distances discussed above.

An interesting feature of the structure of (I) is the geometry of the µ₂-bridging methoxyl ligands. This is the first example of such a group acting as a component of a decavanadium cluster, although it has previously been observed in some other vanadium complexes (Chen & Zubieta, 1993; Hitchcock et al., 1997; Hughes et al., 1994; Mikuriya et al., 1993; Jiang et al., 1998; Herron et al., 1997). The O atom of the methoxyl ligand (O6) is µ₂-bonded to atoms V1 and V2, with bond lengths of 1.952 (2) and 2.007 (2) Å, respectively, which are more similar to the distances between the V atoms and the µ₃-bridging oxo ligands than to the µ₂-bridging ones. The displacement of atom O6 from the V1/V2/C1 plane is 0.2507 (33) Å. The angles C1—O6—V1 and C1—O6—V2 are 122.0 (2) and 121.0 (2)°, respectively. These features imply that the µ₂-bridging atom O6 bonds to V1 and V2 with sp² hybrid orbitals.

In the crystal structure of (I), the six-membered piperidine rings occur in a chair conformation. The puckering parameters (Cremer & Pople, 1975) are σ = 2.8 (4)°, ϕ = 172 (9)° and Q = 0.551 (5) Å for the N1 ring, and σ = 6.1 (5)°, ϕ = −174 (5)° and Q = 0.553 (5) Å for the N2 ring. Each piperidinium cation interacts with two [V₁₀O₂₆(OCH₃)₂]⁴⁻ anions via N—H···O hydrogen bonds (Table 2), which results in a three-dimensional hydrogen-bonding structure, with the N2 H atoms joining decavanadate units along the (101) plane and the N1 oH atoms binding along the [100] direction (Fig. 2).

Experimental top

Although the initial scope of this work was to prepare a polynuclear complex of oxovanadium(IV) bridged by pyromellitic acid, during the synthetic process a pentavalent species was obtained. It was also found that the decavanadate was easily generated in the experimental pH conditions used, a fact already mentioned in some earlier references (Pope, 1983; Duraisamy et al., 2000). Thus, the serendipitous presence of pyromellitic acid became important to the formation of the title compound, obtained as follows. Pyromellitic acid (0.0254 g, 0.1 mmol) was dissolved in methanol (5 ml) containing piperidine (0.034 g, 0.4 mmol). VO(acac)₂ (0.053 g, 0.2 mmol) dissolved in methanol (5 ml) was then added dropwise to the solution. The mixture was heated at reflux with stirring for 7 h. The reaction solution was filtered and concentrated by slow evaporation at room temperature for several days, and then orange crystals of the title compound of suitable size for X-ray analysis were obtained from the mixed solution.

Computing details top

Data collection: SMART (Bruker, 2002); cell refinement: SAINT (Bruker, 2002); data reduction: SAINT; program(s) used to solve structure: SHELXS97 (Sheldrick, 1997); program(s) used to refine structure: SHELXL97 (Sheldrick, 1997); molecular graphics: XP (Siemens, 1994)); software used to prepare material for publication: WinGX (Farrugia, 1999).

Figures top

	Fig. 1. The molecular structure of (I), with 30% probability displacement ellipsoids. [Symmetry code: (i) −x + 1, −y, −z + 1.]
	Fig. 2. A view of the three-dimensional hydrogen-bonding structure of (I). N2 H atoms join decavanadate units along the (101) plane and N1 H atoms bind along the [100] direction. Dotted lines indicate hydrogen bonds. [Symmetry codes: (i) −x + 2, −y, −z + 1; (ii) −x + 3/2, y + 1/2, −z + 1/2.]

Tetrapiperidinium di-µ-methoxy-di-µ₅-oxo-tetra-µ₃-oxo-dodeca-µ₂-oxo-octaoxodecavanadate top

Crystal data top

(C₅H₁₂N)₄[V₁₀(CH₃O)₂O₂₆]	F(000) = 1336
M_r = 1332.09	D_x = 2.021 Mg m⁻³
Monoclinic, P2₁/n	Mo Kα radiation, λ = 0.71073 Å
Hall symbol: -P 2yn	Cell parameters from 5269 reflections
a = 10.546 (2) Å	θ = 2.3–23.3°
b = 12.950 (3) Å	µ = 2.13 mm⁻¹
c = 16.033 (3) Å	T = 296 K
β = 90.58 (3)°	Block, orange
V = 2189.5 (8) Å³	0.22 × 0.18 × 0.14 mm
Z = 2

Data collection top

Bruker APEX area-detector diffractometer	3957 independent reflections
Radiation source: fine-focus sealed tube	3226 reflections with I > 2σ(I)
Graphite monochromator	R_int = 0.021
ϕ and ω scans	θ_max = 25.2°, θ_min = 2.0°
Absorption correction: multi-scan SADABS (Sheldrick, 2003)	h = −12→12
T_min = 0.639, T_max = 0.734	k = −10→15
11580 measured reflections	l = −19→19

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)] = 0.031	Hydrogen site location: inferred from neighbouring sites
wR(F²) = 0.093	H-atom parameters constrained
S = 1.02	w = 1/[σ²(F_o²) + (0.0502P)² + 2.2417P] where P = (F_o² + 2F_c²)/3
3957 reflections	(Δ/σ)_max = 0.001
290 parameters	Δρ_max = 0.73 e Å⁻³
0 restraints	Δρ_min = −0.45 e Å⁻³

Crystal data top

(C₅H₁₂N)₄[V₁₀(CH₃O)₂O₂₆]	V = 2189.5 (8) Å³
M_r = 1332.09	Z = 2
Monoclinic, P2₁/n	Mo Kα radiation
a = 10.546 (2) Å	µ = 2.13 mm⁻¹
b = 12.950 (3) Å	T = 296 K
c = 16.033 (3) Å	0.22 × 0.18 × 0.14 mm
β = 90.58 (3)°

Data collection top

Bruker APEX area-detector diffractometer	3957 independent reflections
Absorption correction: multi-scan SADABS (Sheldrick, 2003)	3226 reflections with I > 2σ(I)
T_min = 0.639, T_max = 0.734	R_int = 0.021
11580 measured reflections

Refinement top

R[F² > 2σ(F²)] = 0.031	0 restraints
wR(F²) = 0.093	H-atom parameters constrained
S = 1.02	Δρ_max = 0.73 e Å⁻³
3957 reflections	Δρ_min = −0.45 e Å⁻³
290 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
V1	0.55955 (5)	0.16947 (4)	0.34238 (3)	0.03288 (15)
V2	0.29905 (5)	0.05938 (4)	0.40506 (3)	0.03148 (15)
V3	0.48827 (6)	−0.04982 (4)	0.28905 (3)	0.03491 (16)
V4	0.71648 (5)	−0.01575 (4)	0.40962 (3)	0.03057 (15)
V5	0.53063 (5)	0.12000 (4)	0.52507 (3)	0.02620 (14)
O1	0.5892 (2)	0.27549 (19)	0.29517 (15)	0.0455 (6)
O2	0.1520 (2)	0.0890 (2)	0.40532 (15)	0.0469 (6)
O3	0.4734 (3)	−0.1153 (2)	0.20495 (14)	0.0503 (7)
O4	0.8654 (2)	−0.0404 (2)	0.41318 (15)	0.0454 (6)
O5	0.5439 (2)	0.16155 (17)	0.62463 (13)	0.0343 (5)
O6	0.3717 (2)	0.18438 (17)	0.35708 (13)	0.0354 (5)
O7	0.5255 (2)	0.08004 (18)	0.25617 (13)	0.0358 (5)
O8	0.71665 (19)	0.11729 (17)	0.36063 (13)	0.0333 (5)
O9	0.5617 (2)	0.22085 (16)	0.46216 (13)	0.0341 (5)
O10	0.3178 (2)	−0.01297 (19)	0.31346 (13)	0.0381 (5)
O11	0.6598 (2)	−0.07721 (17)	0.31687 (13)	0.0350 (5)
O12	0.70014 (19)	0.05908 (16)	0.52069 (13)	0.0291 (5)
O13	0.35043 (19)	0.12186 (16)	0.51800 (13)	0.0289 (5)
O14	0.50738 (18)	0.02909 (15)	0.41969 (12)	0.0259 (4)
C1	0.3118 (5)	0.2851 (4)	0.3693 (3)	0.0753 (14)
H1A	0.2213	0.2772	0.3681	0.113*
H1B	0.3370	0.3311	0.3255	0.113*
H1C	0.3379	0.3130	0.4222	0.113*
N1	0.9223 (3)	0.1709 (3)	0.5428 (2)	0.0550 (9)
H1D	0.9806	0.1201	0.5440	0.066*
H1E	0.8481	0.1432	0.5259	0.066*
C2	0.9617 (4)	0.2507 (4)	0.4821 (3)	0.0681 (13)
H2A	0.9626	0.2209	0.4266	0.082*
H2B	1.0471	0.2735	0.4956	0.082*
C3	0.8744 (5)	0.3413 (4)	0.4826 (3)	0.0674 (12)
H3A	0.7912	0.3200	0.4628	0.081*
H3B	0.9059	0.3937	0.4449	0.081*
C4	0.8631 (5)	0.3867 (3)	0.5695 (3)	0.0652 (12)
H4A	0.9445	0.4141	0.5875	0.078*
H4B	0.8022	0.4428	0.5688	0.078*
C5	0.8209 (4)	0.3045 (4)	0.6289 (3)	0.0640 (12)
H5A	0.8179	0.3331	0.6847	0.077*
H5B	0.7359	0.2824	0.6136	0.077*
C6	0.9075 (4)	0.2132 (4)	0.6287 (3)	0.0656 (13)
H6A	0.9899	0.2334	0.6506	0.079*
H6B	0.8736	0.1600	0.6648	0.079*
N2	0.8609 (3)	0.1875 (2)	0.2268 (2)	0.0506 (8)
H2C	0.8684	0.2557	0.2364	0.061*
H2D	0.8126	0.1608	0.2674	0.061*
C7	0.9880 (4)	0.1401 (4)	0.2321 (3)	0.0593 (11)
H7A	1.0451	0.1770	0.1955	0.071*
H7B	1.0204	0.1464	0.2887	0.071*
C8	0.9851 (5)	0.0301 (4)	0.2082 (3)	0.0753 (14)
H8A	0.9371	−0.0084	0.2491	0.090*
H8B	1.0710	0.0031	0.2082	0.090*
C9	0.9248 (6)	0.0149 (4)	0.1214 (3)	0.0876 (17)
H9A	0.9754	0.0491	0.0795	0.105*
H9B	0.9206	−0.0581	0.1080	0.105*
C10	0.7934 (5)	0.0603 (4)	0.1226 (3)	0.0785 (15)
H10A	0.7545	0.0524	0.0679	0.094*
H10B	0.7423	0.0226	0.1623	0.094*
C11	0.7948 (4)	0.1724 (3)	0.1457 (3)	0.0602 (11)
H11A	0.8375	0.2117	0.1028	0.072*
H11B	0.7084	0.1976	0.1495	0.072*

Atomic displacement parameters (Å²) top

	U¹¹	U²²	U³³	U¹²	U¹³	U²³
V1	0.0343 (3)	0.0323 (3)	0.0321 (3)	0.0013 (2)	0.0042 (2)	0.0060 (2)
V2	0.0240 (3)	0.0392 (3)	0.0311 (3)	0.0025 (2)	−0.0030 (2)	0.0046 (2)
V3	0.0400 (3)	0.0383 (3)	0.0263 (3)	−0.0009 (3)	−0.0003 (2)	−0.0031 (2)
V4	0.0235 (3)	0.0373 (3)	0.0310 (3)	0.0028 (2)	0.0041 (2)	0.0030 (2)
V5	0.0262 (3)	0.0250 (3)	0.0274 (3)	−0.0012 (2)	0.0007 (2)	−0.0020 (2)
O1	0.0525 (15)	0.0389 (14)	0.0451 (14)	−0.0004 (12)	0.0047 (11)	0.0105 (11)
O2	0.0271 (12)	0.0667 (17)	0.0466 (14)	0.0085 (12)	−0.0058 (10)	0.0084 (13)
O3	0.0632 (17)	0.0550 (16)	0.0328 (13)	−0.0058 (13)	−0.0003 (12)	−0.0105 (12)
O4	0.0258 (12)	0.0628 (17)	0.0476 (14)	0.0078 (11)	0.0059 (10)	0.0110 (12)
O5	0.0385 (13)	0.0313 (12)	0.0329 (12)	−0.0032 (10)	−0.0011 (9)	−0.0045 (10)
O6	0.0348 (12)	0.0352 (12)	0.0363 (12)	0.0074 (10)	0.0006 (9)	0.0092 (10)
O7	0.0372 (13)	0.0424 (13)	0.0279 (11)	0.0016 (10)	−0.0002 (9)	0.0061 (10)
O8	0.0276 (11)	0.0378 (13)	0.0345 (12)	−0.0033 (9)	0.0047 (9)	0.0054 (10)
O9	0.0383 (13)	0.0277 (12)	0.0365 (12)	−0.0037 (10)	0.0030 (9)	0.0008 (9)
O10	0.0328 (12)	0.0499 (14)	0.0314 (12)	−0.0056 (11)	−0.0062 (9)	0.0008 (10)
O11	0.0370 (13)	0.0385 (13)	0.0297 (11)	0.0051 (10)	0.0063 (9)	−0.0007 (10)
O12	0.0226 (10)	0.0328 (12)	0.0318 (11)	−0.0036 (9)	−0.0026 (8)	0.0020 (9)
O13	0.0263 (11)	0.0293 (11)	0.0311 (11)	0.0045 (9)	0.0020 (8)	0.0006 (9)
O14	0.0231 (10)	0.0297 (11)	0.0249 (10)	−0.0006 (9)	0.0000 (8)	0.0011 (9)
C1	0.067 (3)	0.067 (3)	0.092 (4)	0.010 (2)	0.015 (3)	0.013 (3)
N1	0.0315 (16)	0.050 (2)	0.084 (2)	0.0024 (14)	−0.0167 (16)	−0.0081 (18)
C2	0.056 (3)	0.084 (3)	0.064 (3)	−0.004 (2)	0.018 (2)	−0.013 (3)
C3	0.081 (3)	0.065 (3)	0.056 (3)	0.008 (2)	0.006 (2)	0.009 (2)
C4	0.074 (3)	0.049 (3)	0.072 (3)	0.004 (2)	0.005 (2)	−0.007 (2)
C5	0.053 (3)	0.088 (3)	0.051 (2)	−0.021 (2)	0.0053 (19)	−0.025 (2)
C6	0.064 (3)	0.072 (3)	0.060 (3)	−0.020 (2)	−0.021 (2)	0.011 (2)
N2	0.0508 (19)	0.0467 (19)	0.0547 (19)	−0.0080 (15)	0.0131 (15)	0.0082 (15)
C7	0.055 (3)	0.067 (3)	0.056 (2)	0.003 (2)	0.0013 (19)	0.013 (2)
C8	0.087 (4)	0.061 (3)	0.079 (3)	0.017 (3)	0.007 (3)	0.016 (3)
C9	0.131 (5)	0.053 (3)	0.080 (4)	0.008 (3)	0.021 (3)	−0.009 (3)
C10	0.092 (4)	0.075 (3)	0.069 (3)	−0.027 (3)	−0.011 (3)	0.001 (3)
C11	0.052 (2)	0.067 (3)	0.061 (3)	−0.003 (2)	−0.001 (2)	0.014 (2)

Geometric parameters (Å, º) top

V1—O1	1.600 (2)	N1—C6	1.491 (6)
V1—O6	2.007 (2)	N1—H1D	0.9000
V1—O7	1.836 (2)	N1—H1E	0.9000
V1—O8	1.810 (2)	C2—C3	1.491 (6)
V1—O9	2.033 (2)	C2—H2A	0.9700
V1—O14	2.271 (2)	C2—H2B	0.9700
V2—O2	1.598 (2)	C3—C4	1.517 (6)
V2—O6	1.952 (2)	C3—H3A	0.9700
V2—O10	1.755 (2)	C3—H3B	0.9700
V2—O12ⁱ	1.942 (2)	C4—C5	1.498 (6)
V2—O13	2.051 (2)	C4—H4A	0.9700
V2—O14	2.242 (2)	C4—H4B	0.9700
V3—O3	1.600 (2)	C5—C6	1.494 (6)
V3—O5ⁱ	2.033 (2)	C5—H5A	0.9700
V3—O7	1.807 (2)	C5—H5B	0.9700
V3—O10	1.904 (2)	C6—H6A	0.9700
V3—O11	1.893 (2)	C6—H6B	0.9700
V3—O14	2.337 (2)	N2—C7	1.476 (5)
V4—O4	1.603 (2)	N2—C11	1.481 (5)
V4—O8	1.893 (2)	N2—H2C	0.9000
V4—O11	1.784 (2)	N2—H2D	0.9000
V4—O12	2.036 (2)	C7—C8	1.475 (6)
V4—O13ⁱ	1.936 (2)	C7—H7A	0.9700
V4—O14	2.288 (2)	C7—H7B	0.9700
V5—O5	1.689 (2)	C8—C9	1.538 (7)
V5—O9	1.684 (2)	C8—H8A	0.9700
V5—O12	1.956 (2)	C8—H8B	0.9700
V5—O13	1.903 (2)	C9—C10	1.505 (7)
V5—O14	2.072 (2)	C9—H9A	0.9700
V5—O14ⁱ	2.163 (2)	C9—H9B	0.9700
O6—C1	1.463 (5)	C10—C11	1.499 (6)
C1—H1A	0.9600	C10—H10A	0.9700
C1—H1B	0.9600	C10—H10B	0.9700
C1—H1C	0.9600	C11—H11A	0.9700
N1—C2	1.482 (6)	C11—H11B	0.9700

O1—V1—O8	102.36 (12)	O14—V4—V3	48.54 (5)
O1—V1—O7	102.87 (12)	V2ⁱ—V4—V3	122.35 (3)
O8—V1—O7	93.33 (10)	V1—V4—V3	59.04 (2)
O1—V1—O6	99.82 (11)	O9—V5—O5	107.71 (11)
O8—V1—O6	156.91 (9)	O9—V5—O13	98.90 (10)
O7—V1—O6	87.89 (10)	O5—V5—O13	97.20 (10)
O1—V1—O9	99.54 (11)	O9—V5—O12	96.19 (10)
O8—V1—O9	88.16 (10)	O5—V5—O12	95.48 (10)
O7—V1—O9	156.66 (10)	O13—V5—O12	156.29 (9)
O6—V1—O9	81.90 (10)	O9—V5—O14	88.53 (9)
O1—V1—O14	174.02 (11)	O5—V5—O14	163.69 (10)
O8—V1—O14	80.76 (8)	O13—V5—O14	81.30 (9)
O7—V1—O14	81.91 (9)	O12—V5—O14	80.92 (8)
O6—V1—O14	76.58 (8)	O9—V5—O14ⁱ	167.20 (9)
O9—V1—O14	75.33 (8)	O5—V5—O14ⁱ	84.91 (9)
O1—V1—V5	131.58 (9)	O13—V5—O14ⁱ	81.18 (8)
O8—V1—V5	82.24 (7)	O12—V5—O14ⁱ	80.09 (8)
O7—V1—V5	125.18 (7)	O14—V5—O14ⁱ	78.81 (8)
O6—V1—V5	78.27 (7)	O9—V5—V1	39.81 (7)
O9—V1—V5	32.04 (6)	O5—V5—V1	147.33 (8)
O14—V1—V5	43.34 (5)	O13—V5—V1	92.88 (7)
O1—V1—V3	135.51 (10)	O12—V5—V1	87.10 (7)
O8—V1—V3	85.44 (7)	O14—V5—V1	48.79 (6)
O7—V1—V3	32.63 (7)	O14ⁱ—V5—V1	127.44 (6)
O6—V1—V3	83.22 (7)	V5—O5—V3ⁱ	113.82 (11)
O9—V1—V3	124.66 (6)	C1—O6—V1	122.0 (2)
O14—V1—V3	49.37 (5)	C1—O6—V2	121.0 (2)
V5—V1—V3	92.71 (2)	V2—O6—V1	111.01 (10)
O1—V1—V4	136.23 (10)	V3—O7—V1	114.14 (11)
O8—V1—V4	33.99 (7)	V1—O8—V4	113.70 (11)
O7—V1—V4	82.74 (7)	V5—O9—V1	108.15 (11)
O6—V1—V4	123.89 (6)	V2—O10—V3	114.87 (12)
O9—V1—V4	85.63 (7)	V4—O11—V3	115.08 (11)
O14—V1—V4	47.36 (5)	V2ⁱ—O12—V5	107.16 (10)
V5—V1—V4	63.71 (2)	V2ⁱ—O12—V4	99.22 (9)
V3—V1—V4	60.51 (2)	V5—O12—V4	107.99 (10)
O2—V2—O10	104.37 (12)	V5—O13—V4ⁱ	108.97 (10)
O2—V2—O12ⁱ	100.75 (11)	V5—O13—V2	107.60 (10)
O10—V2—O12ⁱ	95.25 (10)	V4ⁱ—O13—V2	98.89 (9)
O2—V2—O6	100.76 (12)	V5—O14—V5ⁱ	101.19 (8)
O10—V2—O6	93.72 (10)	V5—O14—V2	95.38 (8)
O12ⁱ—V2—O6	153.81 (9)	V5ⁱ—O14—V2	90.78 (7)
O2—V2—O13	98.67 (11)	V5—O14—V1	87.88 (8)
O10—V2—O13	156.68 (10)	V5ⁱ—O14—V1	169.99 (10)
O12ⁱ—V2—O13	76.75 (9)	V2—O14—V1	92.61 (7)
O6—V2—O13	85.39 (9)	V5—O14—V4	95.48 (8)
O2—V2—O14	172.79 (11)	V5ⁱ—O14—V4	89.14 (7)
O10—V2—O14	82.84 (9)	V2—O14—V4	168.95 (10)
O12ⁱ—V2—O14	78.42 (8)	V1—O14—V4	85.74 (7)
O6—V2—O14	78.35 (8)	V5—O14—V3	170.98 (10)
O13—V2—O14	74.14 (8)	V5ⁱ—O14—V3	87.83 (7)
O2—V2—V4ⁱ	88.87 (9)	V2—O14—V3	84.68 (7)
O10—V2—V4ⁱ	136.78 (8)	V1—O14—V3	83.11 (7)
O12ⁱ—V2—V4ⁱ	41.55 (6)	V4—O14—V3	84.28 (7)
O6—V2—V4ⁱ	124.49 (7)	O6—C1—H1A	109.5
O13—V2—V4ⁱ	39.14 (6)	O6—C1—H1B	109.5
O14—V2—V4ⁱ	85.84 (6)	H1A—C1—H1B	109.5
O2—V2—V3	138.21 (10)	O6—C1—H1C	109.5
O10—V2—V3	34.06 (7)	H1A—C1—H1C	109.5
O12ⁱ—V2—V3	90.49 (7)	H1B—C1—H1C	109.5
O6—V2—V3	83.31 (7)	C2—N1—C6	112.5 (3)
O13—V2—V3	123.12 (6)	C2—N1—H1D	109.1
O14—V2—V3	48.97 (5)	C6—N1—H1D	109.1
V4ⁱ—V2—V3	123.19 (3)	C2—N1—H1E	109.1
O3—V3—O7	105.52 (12)	C6—N1—H1E	109.1
O3—V3—O11	100.65 (12)	H1D—N1—H1E	107.8
O7—V3—O11	91.91 (10)	N1—C2—C3	111.5 (3)
O3—V3—O10	102.78 (12)	N1—C2—H2A	109.3
O7—V3—O10	92.00 (10)	C3—C2—H2A	109.3
O11—V3—O10	154.25 (10)	N1—C2—H2B	109.3
O3—V3—O5ⁱ	100.41 (11)	C3—C2—H2B	109.3
O7—V3—O5ⁱ	154.07 (9)	H2A—C2—H2B	108.0
O11—V3—O5ⁱ	82.64 (10)	C2—C3—C4	111.4 (4)
O10—V3—O5ⁱ	82.77 (10)	C2—C3—H3A	109.4
O3—V3—O14	173.80 (11)	C4—C3—H3A	109.4
O7—V3—O14	80.65 (9)	C2—C3—H3B	109.4
O11—V3—O14	78.30 (8)	C4—C3—H3B	109.4
O10—V3—O14	77.25 (9)	H3A—C3—H3B	108.0
O5ⁱ—V3—O14	73.42 (8)	C5—C4—C3	109.6 (4)
O3—V3—V1	138.61 (10)	C5—C4—H4A	109.8
O7—V3—V1	33.23 (7)	C3—C4—H4A	109.8
O11—V3—V1	82.90 (7)	C5—C4—H4B	109.8
O10—V3—V1	86.54 (7)	C3—C4—H4B	109.8
O5ⁱ—V3—V1	120.86 (6)	H4A—C4—H4B	108.2
O14—V3—V1	47.52 (5)	C6—C5—C4	112.0 (4)
O3—V3—V2	133.85 (10)	C6—C5—H5A	109.2
O7—V3—V2	83.86 (7)	C4—C5—H5A	109.2
O11—V3—V2	124.51 (7)	C6—C5—H5B	109.2
O10—V3—V2	31.07 (7)	C4—C5—H5B	109.2
O5ⁱ—V3—V2	78.61 (7)	H5A—C5—H5B	107.9
O14—V3—V2	46.35 (5)	N1—C6—C5	111.2 (3)
V1—V3—V2	64.17 (2)	N1—C6—H6A	109.4
O3—V3—V4	132.03 (10)	C5—C6—H6A	109.4
O7—V3—V4	83.11 (7)	N1—C6—H6B	109.4
O11—V3—V4	31.39 (7)	C5—C6—H6B	109.4
O10—V3—V4	124.34 (7)	H6A—C6—H6B	108.0
O5ⁱ—V3—V4	79.09 (6)	C7—N2—C11	114.5 (3)
O14—V3—V4	47.18 (5)	C7—N2—H2C	108.6
V1—V3—V4	60.449 (19)	C11—N2—H2C	108.6
V2—V3—V4	93.53 (2)	C7—N2—H2D	108.6
O4—V4—O11	105.11 (12)	C11—N2—H2D	108.6
O4—V4—O8	100.99 (11)	H2C—N2—H2D	107.6
O11—V4—O8	93.54 (10)	C8—C7—N2	111.7 (4)
O4—V4—O13ⁱ	101.56 (11)	C8—C7—H7A	109.3
O11—V4—O13ⁱ	93.56 (10)	N2—C7—H7A	109.3
O8—V4—O13ⁱ	153.66 (9)	C8—C7—H7B	109.3
O4—V4—O12	98.91 (11)	N2—C7—H7B	109.3
O11—V4—O12	155.59 (9)	H7A—C7—H7B	107.9
O8—V4—O12	85.99 (9)	C7—C8—C9	111.4 (4)
O13ⁱ—V4—O12	77.24 (9)	C7—C8—H8A	109.3
O4—V4—O14	173.09 (11)	C9—C8—H8A	109.3
O11—V4—O14	81.79 (9)	C7—C8—H8B	109.3
O8—V4—O14	78.65 (8)	C9—C8—H8B	109.3
O13ⁱ—V4—O14	77.32 (8)	H8A—C8—H8B	108.0
O12—V4—O14	74.18 (8)	C10—C9—C8	108.1 (4)
O4—V4—V2ⁱ	89.46 (9)	C10—C9—H9A	110.1
O11—V4—V2ⁱ	135.49 (8)	C8—C9—H9A	110.1
O8—V4—V2ⁱ	125.21 (7)	C10—C9—H9B	110.1
O13ⁱ—V4—V2ⁱ	41.97 (6)	C8—C9—H9B	110.1
O12—V4—V2ⁱ	39.23 (6)	H9A—C9—H9B	108.4
O14—V4—V2ⁱ	85.21 (6)	C11—C10—C9	112.0 (4)
O4—V4—V1	133.26 (9)	C11—C10—H10A	109.2
O11—V4—V1	83.24 (8)	C9—C10—H10A	109.2
O8—V4—V1	32.31 (6)	C11—C10—H10B	109.2
O13ⁱ—V4—V1	124.11 (6)	C9—C10—H10B	109.2
O12—V4—V1	83.47 (6)	H10A—C10—H10B	107.9
O14—V4—V1	46.91 (5)	N2—C11—C10	110.4 (4)
V2ⁱ—V4—V1	116.81 (3)	N2—C11—H11A	109.6
O4—V4—V3	138.36 (10)	C10—C11—H11A	109.6
O11—V4—V3	33.53 (7)	N2—C11—H11B	109.6
O8—V4—V3	82.81 (7)	C10—C11—H11B	109.6
O13ⁱ—V4—V3	89.28 (7)	H11A—C11—H11B	108.1
O12—V4—V3	122.72 (6)

O1—V1—V3—O3	6.1 (2)	O2—V2—O6—V1	−177.08 (12)
O8—V1—V3—O3	−96.96 (17)	O10—V2—O6—V1	−71.68 (12)
O7—V1—V3—O3	6.5 (2)	O12ⁱ—V2—O6—V1	38.2 (3)
O6—V1—V3—O3	103.20 (17)	O13—V2—O6—V1	84.96 (11)
O9—V1—V3—O3	178.44 (17)	O14—V2—O6—V1	10.22 (10)
O14—V1—V3—O3	−178.68 (17)	V4ⁱ—V2—O6—V1	86.83 (11)
V5—V1—V3—O3	−178.96 (15)	V3—V2—O6—V1	−39.19 (9)
V4—V1—V3—O3	−121.38 (16)	O1—V1—O6—C1	−32.4 (3)
O1—V1—V3—O7	−0.43 (18)	O8—V1—O6—C1	131.3 (3)
O8—V1—V3—O7	−103.45 (15)	O7—V1—O6—C1	−135.1 (3)
O6—V1—V3—O7	96.71 (15)	O9—V1—O6—C1	65.9 (3)
O9—V1—V3—O7	171.95 (15)	O14—V1—O6—C1	142.7 (3)
O14—V1—V3—O7	174.83 (15)	V5—V1—O6—C1	98.3 (3)
V5—V1—V3—O7	174.56 (13)	V3—V1—O6—C1	−167.5 (3)
V4—V1—V3—O7	−127.87 (13)	V4—V1—O6—C1	145.1 (3)
O1—V1—V3—O11	104.13 (15)	O1—V1—O6—V2	174.73 (13)
O8—V1—V3—O11	1.10 (9)	O8—V1—O6—V2	−21.5 (3)
O7—V1—V3—O11	104.55 (15)	O7—V1—O6—V2	72.03 (12)
O6—V1—V3—O11	−158.74 (9)	O9—V1—O6—V2	−86.92 (11)
O9—V1—V3—O11	−83.49 (11)	O14—V1—O6—V2	−10.16 (10)
O14—V1—V3—O11	−80.62 (9)	V5—V1—O6—V2	−54.58 (9)
V5—V1—V3—O11	−80.89 (7)	V3—V1—O6—V2	39.62 (9)
V4—V1—V3—O11	−23.32 (7)	V4—V1—O6—V2	−7.77 (14)
O1—V1—V3—O10	−99.41 (15)	O3—V3—O7—V1	−175.55 (13)
O8—V1—V3—O10	157.57 (9)	O11—V3—O7—V1	−73.95 (13)
O7—V1—V3—O10	−98.98 (15)	O10—V3—O7—V1	80.59 (13)
O6—V1—V3—O10	−2.27 (9)	O5ⁱ—V3—O7—V1	3.1 (3)
O9—V1—V3—O10	72.97 (11)	O14—V3—O7—V1	3.86 (11)
O14—V1—V3—O10	75.85 (10)	V2—V3—O7—V1	50.56 (11)
V5—V1—V3—O10	75.58 (7)	V4—V3—O7—V1	−43.76 (10)
V4—V1—V3—O10	133.15 (7)	O1—V1—O7—V3	179.69 (13)
O1—V1—V3—O5ⁱ	−178.86 (15)	O8—V1—O7—V3	76.20 (13)
O8—V1—V3—O5ⁱ	78.11 (10)	O6—V1—O7—V3	−80.71 (13)
O7—V1—V3—O5ⁱ	−178.44 (15)	O9—V1—O7—V3	−16.9 (3)
O6—V1—V3—O5ⁱ	−81.73 (10)	O14—V1—O7—V3	−3.96 (11)
O9—V1—V3—O5ⁱ	−6.48 (12)	V5—V1—O7—V3	−6.66 (16)
O14—V1—V3—O5ⁱ	−3.61 (10)	V4—V1—O7—V3	43.84 (10)
V5—V1—V3—O5ⁱ	−3.88 (8)	O1—V1—O8—V4	−175.72 (13)
V4—V1—V3—O5ⁱ	53.69 (8)	O7—V1—O8—V4	−71.76 (13)
O1—V1—V3—O14	−175.25 (15)	O6—V1—O8—V4	20.7 (3)
O8—V1—V3—O14	81.72 (10)	O9—V1—O8—V4	84.91 (12)
O7—V1—V3—O14	−174.83 (15)	O14—V1—O8—V4	9.48 (11)
O6—V1—V3—O14	−78.12 (9)	V5—V1—O8—V4	53.30 (10)
O9—V1—V3—O14	−2.87 (10)	V3—V1—O8—V4	−40.07 (10)
V5—V1—V3—O14	−0.27 (6)	O4—V4—O8—V1	177.56 (13)
V4—V1—V3—O14	57.30 (7)	O11—V4—O8—V1	71.42 (13)
O1—V1—V3—V2	−121.88 (14)	O13ⁱ—V4—O8—V1	−34.0 (3)
O8—V1—V3—V2	135.10 (7)	O12—V4—O8—V1	−84.12 (12)
O7—V1—V3—V2	−121.45 (13)	O14—V4—O8—V1	−9.47 (11)
O6—V1—V3—V2	−24.75 (6)	V2ⁱ—V4—O8—V1	−85.24 (12)
O9—V1—V3—V2	50.50 (8)	V3—V4—O8—V1	39.58 (10)
O14—V1—V3—V2	53.37 (7)	O5—V5—O9—V1	175.68 (10)
V5—V1—V3—V2	53.10 (3)	O13—V5—O9—V1	−83.76 (11)
V4—V1—V3—V2	110.67 (2)	O12—V5—O9—V1	77.89 (11)
O1—V1—V3—V4	127.45 (14)	O14—V5—O9—V1	−2.81 (10)
O8—V1—V3—V4	24.42 (7)	O14ⁱ—V5—O9—V1	5.6 (5)
O7—V1—V3—V4	127.87 (13)	O1—V1—O9—V5	179.50 (13)
O6—V1—V3—V4	−135.42 (7)	O8—V1—O9—V5	−78.27 (12)
O9—V1—V3—V4	−60.17 (8)	O7—V1—O9—V5	15.9 (3)
O14—V1—V3—V4	−57.30 (7)	O6—V1—O9—V5	80.82 (12)
V5—V1—V3—V4	−57.57 (3)	O14—V1—O9—V5	2.65 (10)
O2—V2—V3—O3	−9.5 (2)	V3—V1—O9—V5	4.90 (14)
O10—V2—V3—O3	−1.37 (19)	V4—V1—O9—V5	−44.32 (10)
O12ⁱ—V2—V3—O3	97.29 (15)	O2—V2—O10—V3	174.39 (14)
O6—V2—V3—O3	−108.22 (15)	O12ⁱ—V2—O10—V3	−83.08 (13)
O13—V2—V3—O3	171.75 (15)	O6—V2—O10—V3	72.28 (13)
O14—V2—V3—O3	171.42 (15)	O13—V2—O10—V3	−14.7 (3)
V4ⁱ—V2—V3—O3	124.58 (14)	O14—V2—O10—V3	−5.47 (12)
O2—V2—V3—O7	96.11 (16)	V4ⁱ—V2—O10—V3	−81.56 (15)
O10—V2—V3—O7	104.28 (15)	O3—V3—O10—V2	178.99 (14)
O12ⁱ—V2—V3—O7	−157.05 (9)	O7—V3—O10—V2	−74.60 (14)
O6—V2—V3—O7	−2.57 (9)	O11—V3—O10—V2	24.0 (3)
O13—V2—V3—O7	−82.60 (10)	O5ⁱ—V3—O10—V2	79.90 (13)
O14—V2—V3—O7	−82.93 (10)	O14—V3—O10—V2	5.34 (12)
V4ⁱ—V2—V3—O7	−129.76 (7)	V1—V3—O10—V2	−41.81 (12)
O2—V2—V3—O11	−175.80 (17)	V4—V3—O10—V2	8.42 (17)
O10—V2—V3—O11	−167.63 (17)	O4—V4—O11—V3	−173.70 (13)
O12ⁱ—V2—V3—O11	−68.97 (11)	O8—V4—O11—V3	−71.32 (13)
O6—V2—V3—O11	85.52 (11)	O13ⁱ—V4—O11—V3	83.31 (13)
O13—V2—V3—O11	5.49 (12)	O12—V4—O11—V3	16.8 (3)
O14—V2—V3—O11	5.16 (11)	O14—V4—O11—V3	6.67 (11)
V4ⁱ—V2—V3—O11	−41.67 (9)	V2ⁱ—V4—O11—V3	81.19 (15)
O2—V2—V3—O10	−8.2 (2)	V1—V4—O11—V3	−40.64 (10)
O12ⁱ—V2—V3—O10	98.66 (15)	O3—V3—O11—V4	179.63 (14)
O6—V2—V3—O10	−106.85 (15)	O7—V3—O11—V4	73.44 (13)
O13—V2—V3—O10	173.12 (16)	O10—V3—O11—V4	−25.2 (3)
O14—V2—V3—O10	172.79 (16)	O5ⁱ—V3—O11—V4	−81.11 (13)
V4ⁱ—V2—V3—O10	125.96 (14)	O14—V3—O11—V4	−6.60 (11)
O2—V2—V3—O5ⁱ	−103.09 (16)	V1—V3—O11—V4	41.39 (11)
O10—V2—V3—O5ⁱ	−94.92 (15)	V2—V3—O11—V4	−10.41 (16)
O12ⁱ—V2—V3—O5ⁱ	3.75 (8)	O9—V5—O12—V2ⁱ	176.56 (10)
O6—V2—V3—O5ⁱ	158.23 (9)	O5—V5—O12—V2ⁱ	68.04 (12)
O13—V2—V3—O5ⁱ	78.20 (10)	O13—V5—O12—V2ⁱ	−54.1 (3)
O14—V2—V3—O5ⁱ	77.87 (9)	O14—V5—O12—V2ⁱ	−95.93 (10)
V4ⁱ—V2—V3—O5ⁱ	31.04 (7)	O14ⁱ—V5—O12—V2ⁱ	−15.81 (9)
O2—V2—V3—O14	179.03 (16)	V1—V5—O12—V2ⁱ	−144.63 (9)
O10—V2—V3—O14	−172.79 (16)	O9—V5—O12—V4	−77.38 (11)
O12ⁱ—V2—V3—O14	−74.13 (9)	O5—V5—O12—V4	174.10 (10)
O6—V2—V3—O14	80.36 (9)	O13—V5—O12—V4	52.0 (3)
O13—V2—V3—O14	0.33 (10)	O14—V5—O12—V4	10.13 (9)
V4ⁱ—V2—V3—O14	−46.84 (7)	O14ⁱ—V5—O12—V4	90.25 (10)
O2—V2—V3—V1	124.15 (15)	V1—V5—O12—V4	−38.57 (8)
O10—V2—V3—V1	132.33 (14)	O4—V4—O12—V2ⁱ	−78.04 (12)
O12ⁱ—V2—V3—V1	−129.01 (6)	O11—V4—O12—V2ⁱ	91.7 (2)
O6—V2—V3—V1	25.48 (7)	O8—V4—O12—V2ⁱ	−178.56 (9)
O13—V2—V3—V1	−54.55 (7)	O13ⁱ—V4—O12—V2ⁱ	21.89 (8)
O14—V2—V3—V1	−54.88 (7)	O14—V4—O12—V2ⁱ	102.12 (9)
V4ⁱ—V2—V3—V1	−101.72 (3)	V1—V4—O12—V2ⁱ	149.09 (7)
O2—V2—V3—V4	178.79 (15)	V3—V4—O12—V2ⁱ	102.63 (8)
O10—V2—V3—V4	−173.04 (14)	O4—V4—O12—V5	170.43 (12)
O12ⁱ—V2—V3—V4	−74.38 (6)	O11—V4—O12—V5	−19.8 (3)
O6—V2—V3—V4	80.11 (7)	O8—V4—O12—V5	69.92 (10)
O13—V2—V3—V4	0.08 (7)	O13ⁱ—V4—O12—V5	−89.64 (10)
O14—V2—V3—V4	−0.25 (7)	O14—V4—O12—V5	−9.41 (8)
V4ⁱ—V2—V3—V4	−47.08 (4)	V2ⁱ—V4—O12—V5	−111.53 (12)
O1—V1—V4—O4	2.75 (19)	V1—V4—O12—V5	37.56 (8)
O8—V1—V4—O4	−3.29 (17)	V3—V4—O12—V5	−8.89 (12)
O7—V1—V4—O4	103.80 (15)	O9—V5—O13—V4ⁱ	−177.11 (11)
O6—V1—V4—O4	−173.69 (15)	O5—V5—O13—V4ⁱ	−67.84 (12)
O9—V1—V4—O4	−96.48 (15)	O12—V5—O13—V4ⁱ	54.0 (3)
O14—V1—V4—O4	−170.52 (15)	O14—V5—O13—V4ⁱ	95.76 (10)
V5—V1—V4—O4	−120.91 (14)	O14ⁱ—V5—O13—V4ⁱ	15.84 (10)
V3—V1—V4—O4	129.21 (13)	V1—V5—O13—V4ⁱ	143.30 (8)
O1—V1—V4—O11	−101.65 (15)	O9—V5—O13—V2	76.59 (11)
O8—V1—V4—O11	−107.70 (15)	O5—V5—O13—V2	−174.13 (10)
O7—V1—V4—O11	−0.61 (10)	O12—V5—O13—V2	−52.3 (3)
O6—V1—V4—O11	81.91 (11)	O14—V5—O13—V2	−10.53 (9)
O9—V1—V4—O11	159.11 (9)	O14ⁱ—V5—O13—V2	−90.45 (10)
O14—V1—V4—O11	85.07 (10)	V1—V5—O13—V2	37.01 (8)
V5—V1—V4—O11	134.69 (7)	O2—V2—O13—V5	−169.39 (12)
V3—V1—V4—O11	24.81 (7)	O10—V2—O13—V5	19.5 (3)
O1—V1—V4—O8	6.04 (18)	O12ⁱ—V2—O13—V5	91.52 (10)
O7—V1—V4—O8	107.09 (15)	O6—V2—O13—V5	−69.19 (11)
O6—V1—V4—O8	−170.40 (15)	O14—V2—O13—V5	9.99 (9)
O9—V1—V4—O8	−93.19 (14)	V4ⁱ—V2—O13—V5	113.26 (13)
O14—V1—V4—O8	−167.23 (14)	V3—V2—O13—V5	9.73 (12)
V5—V1—V4—O8	−117.62 (13)	O2—V2—O13—V4ⁱ	77.35 (12)
V3—V1—V4—O8	132.50 (13)	O10—V2—O13—V4ⁱ	−93.8 (3)
O1—V1—V4—O13ⁱ	168.63 (15)	O12ⁱ—V2—O13—V4ⁱ	−21.74 (8)
O8—V1—V4—O13ⁱ	162.58 (15)	O6—V2—O13—V4ⁱ	177.55 (9)
O7—V1—V4—O13ⁱ	−90.33 (11)	O14—V2—O13—V4ⁱ	−103.26 (9)
O6—V1—V4—O13ⁱ	−7.81 (12)	V3—V2—O13—V4ⁱ	−103.52 (8)
O9—V1—V4—O13ⁱ	69.39 (10)	O9—V5—O14—V5ⁱ	178.11 (10)
O14—V1—V4—O13ⁱ	−4.65 (10)	O5—V5—O14—V5ⁱ	3.2 (4)
V5—V1—V4—O13ⁱ	44.97 (8)	O13—V5—O14—V5ⁱ	−82.65 (9)
V3—V1—V4—O13ⁱ	−64.91 (8)	O12—V5—O14—V5ⁱ	81.61 (9)
O1—V1—V4—O12	98.87 (15)	O14ⁱ—V5—O14—V5ⁱ	0.0
O8—V1—V4—O12	92.83 (14)	V1—V5—O14—V5ⁱ	175.72 (11)
O7—V1—V4—O12	−160.08 (9)	O9—V5—O14—V2	−90.03 (10)
O6—V1—V4—O12	−77.57 (10)	O5—V5—O14—V2	95.1 (3)
O9—V1—V4—O12	−0.37 (8)	O13—V5—O14—V2	9.21 (8)
O14—V1—V4—O12	−74.41 (9)	O12—V5—O14—V2	173.47 (9)
V5—V1—V4—O12	−24.79 (6)	O14ⁱ—V5—O14—V2	91.86 (9)
V3—V1—V4—O12	−134.67 (6)	V1—V5—O14—V2	−92.42 (8)
O1—V1—V4—O14	173.28 (15)	O9—V5—O14—V1	2.39 (9)
O8—V1—V4—O14	167.23 (14)	O5—V5—O14—V1	−172.5 (3)
O7—V1—V4—O14	−85.67 (10)	O13—V5—O14—V1	101.63 (8)
O6—V1—V4—O14	−3.16 (10)	O12—V5—O14—V1	−94.11 (8)
O9—V1—V4—O14	74.04 (9)	O14ⁱ—V5—O14—V1	−175.72 (11)
V5—V1—V4—O14	49.62 (7)	O9—V5—O14—V4	87.90 (9)
V3—V1—V4—O14	−60.26 (7)	O5—V5—O14—V4	−87.0 (3)
O1—V1—V4—V2ⁱ	120.22 (14)	O13—V5—O14—V4	−172.86 (9)
O8—V1—V4—V2ⁱ	114.17 (13)	O12—V5—O14—V4	−8.61 (8)
O7—V1—V4—V2ⁱ	−138.74 (7)	O14ⁱ—V5—O14—V4	−90.21 (9)
O6—V1—V4—V2ⁱ	−56.22 (9)	V1—V5—O14—V4	85.51 (7)
O9—V1—V4—V2ⁱ	20.98 (7)	O10—V2—O14—V5	175.00 (10)
O14—V1—V4—V2ⁱ	−53.06 (7)	O12ⁱ—V2—O14—V5	−88.12 (9)
V5—V1—V4—V2ⁱ	−3.44 (2)	O6—V2—O14—V5	79.69 (9)
V3—V1—V4—V2ⁱ	−113.32 (3)	O13—V2—O14—V5	−8.78 (8)
O1—V1—V4—V3	−126.46 (14)	V4ⁱ—V2—O14—V5	−46.80 (6)
O8—V1—V4—V3	−132.50 (13)	V3—V2—O14—V5	170.94 (10)
O7—V1—V4—V3	−25.41 (7)	O10—V2—O14—V5ⁱ	−83.68 (10)
O6—V1—V4—V3	57.10 (8)	O12ⁱ—V2—O14—V5ⁱ	13.20 (8)
O9—V1—V4—V3	134.30 (7)	O6—V2—O14—V5ⁱ	−178.99 (9)
O14—V1—V4—V3	60.26 (7)	O13—V2—O14—V5ⁱ	92.54 (8)
V5—V1—V4—V3	109.88 (3)	V4ⁱ—V2—O14—V5ⁱ	54.52 (5)
O3—V3—V4—O4	8.67 (19)	V3—V2—O14—V5ⁱ	−87.74 (7)
O7—V3—V4—O4	−96.04 (16)	O10—V2—O14—V1	86.89 (10)
O11—V3—V4—O4	9.17 (19)	O12ⁱ—V2—O14—V1	−176.23 (9)
O10—V3—V4—O4	176.24 (16)	O6—V2—O14—V1	−8.42 (8)
O5ⁱ—V3—V4—O4	102.91 (16)	O13—V2—O14—V1	−96.89 (8)
O14—V3—V4—O4	−179.66 (16)	V4ⁱ—V2—O14—V1	−134.91 (6)
V1—V3—V4—O4	−121.87 (14)	V3—V2—O14—V1	82.83 (7)
V2—V3—V4—O4	−179.41 (14)	O10—V2—O14—V4	5.8 (5)
O3—V3—V4—O11	−0.50 (18)	O12ⁱ—V2—O14—V4	102.7 (5)
O7—V3—V4—O11	−105.21 (15)	O6—V2—O14—V4	−89.5 (5)
O10—V3—V4—O11	167.07 (16)	O13—V2—O14—V4	−178.0 (5)
O5ⁱ—V3—V4—O11	93.74 (15)	V4ⁱ—V2—O14—V4	144.0 (5)
O14—V3—V4—O11	171.17 (15)	V3—V2—O14—V4	1.8 (5)
V1—V3—V4—O11	−131.04 (13)	O10—V2—O14—V3	4.06 (9)
V2—V3—V4—O11	171.42 (13)	O12ⁱ—V2—O14—V3	100.95 (8)
O3—V3—V4—O8	107.15 (15)	O6—V2—O14—V3	−91.25 (8)
O7—V3—V4—O8	2.43 (9)	O13—V2—O14—V3	−179.71 (8)
O11—V3—V4—O8	107.64 (15)	V4ⁱ—V2—O14—V3	142.26 (5)
O10—V3—V4—O8	−85.28 (11)	O8—V1—O14—V5	88.47 (9)
O5ⁱ—V3—V4—O8	−158.61 (9)	O7—V1—O14—V5	−176.79 (9)
O14—V3—V4—O8	−81.19 (9)	O6—V1—O14—V5	−87.04 (9)
V1—V3—V4—O8	−23.40 (7)	O9—V1—O14—V5	−2.05 (8)
V2—V3—V4—O8	−80.94 (7)	V3—V1—O14—V5	−179.60 (9)
O3—V3—V4—O13ⁱ	−98.04 (15)	V4—V1—O14—V5	95.66 (8)
O7—V3—V4—O13ⁱ	157.25 (9)	O8—V1—O14—V5ⁱ	−66.6 (6)
O11—V3—V4—O13ⁱ	−97.54 (15)	O7—V1—O14—V5ⁱ	28.1 (6)
O10—V3—V4—O13ⁱ	69.53 (11)	O6—V1—O14—V5ⁱ	117.9 (6)
O5ⁱ—V3—V4—O13ⁱ	−3.80 (9)	O9—V1—O14—V5ⁱ	−157.2 (6)
O14—V3—V4—O13ⁱ	73.63 (9)	V5—V1—O14—V5ⁱ	−155.1 (6)
V1—V3—V4—O13ⁱ	131.42 (6)	V3—V1—O14—V5ⁱ	25.3 (5)
V2—V3—V4—O13ⁱ	73.88 (6)	V4—V1—O14—V5ⁱ	−59.4 (5)
O3—V3—V4—O12	−172.33 (15)	O8—V1—O14—V2	−176.24 (9)
O7—V3—V4—O12	82.95 (10)	O7—V1—O14—V2	−81.50 (9)
O11—V3—V4—O12	−171.84 (15)	O6—V1—O14—V2	8.25 (8)
O10—V3—V4—O12	−4.76 (12)	O9—V1—O14—V2	93.24 (9)
O5ⁱ—V3—V4—O12	−78.09 (10)	V5—V1—O14—V2	95.29 (8)
O14—V3—V4—O12	−0.66 (10)	V3—V1—O14—V2	−84.31 (7)
V1—V3—V4—O12	57.12 (7)	V4—V1—O14—V2	−169.05 (10)
V2—V3—V4—O12	−0.42 (8)	O8—V1—O14—V4	−7.19 (8)
O3—V3—V4—O14	−171.67 (15)	O7—V1—O14—V4	87.55 (9)
O7—V3—V4—O14	83.62 (10)	O6—V1—O14—V4	177.30 (9)
O11—V3—V4—O14	−171.17 (15)	O9—V1—O14—V4	−97.71 (9)
O10—V3—V4—O14	−4.10 (11)	V5—V1—O14—V4	−95.66 (8)
O5ⁱ—V3—V4—O14	−77.43 (9)	V3—V1—O14—V4	84.74 (7)
V1—V3—V4—O14	57.79 (7)	O8—V1—O14—V3	−91.93 (9)
V2—V3—V4—O14	0.25 (7)	O7—V1—O14—V3	2.81 (8)
O3—V3—V4—V2ⁱ	−125.40 (13)	O6—V1—O14—V3	92.57 (8)
O7—V3—V4—V2ⁱ	129.88 (7)	O9—V1—O14—V3	177.56 (8)
O11—V3—V4—V2ⁱ	−124.91 (13)	V5—V1—O14—V3	179.60 (9)
O10—V3—V4—V2ⁱ	42.17 (10)	V4—V1—O14—V3	−84.74 (7)
O5ⁱ—V3—V4—V2ⁱ	−31.16 (7)	O11—V4—O14—V5	−175.85 (10)
O14—V3—V4—V2ⁱ	46.26 (7)	O8—V4—O14—V5	−80.53 (9)
V1—V3—V4—V2ⁱ	104.05 (3)	O13ⁱ—V4—O14—V5	88.60 (9)
V2—V3—V4—V2ⁱ	46.51 (4)	O12—V4—O14—V5	8.48 (8)
O3—V3—V4—V1	130.55 (13)	V2ⁱ—V4—O14—V5	46.84 (6)
O7—V3—V4—V1	25.83 (7)	V1—V4—O14—V5	−87.45 (8)
O11—V3—V4—V1	131.04 (13)	V3—V4—O14—V5	−170.94 (10)
O10—V3—V4—V1	−61.88 (9)	O11—V4—O14—V5ⁱ	82.99 (9)
O5ⁱ—V3—V4—V1	−135.21 (7)	O8—V4—O14—V5ⁱ	178.30 (9)
O14—V3—V4—V1	−57.79 (7)	O13ⁱ—V4—O14—V5ⁱ	−12.56 (8)
V2—V3—V4—V1	−57.54 (2)	O12—V4—O14—V5ⁱ	−92.68 (8)
O1—V1—V5—O9	−0.66 (17)	V2ⁱ—V4—O14—V5ⁱ	−54.33 (5)
O8—V1—V5—O9	99.01 (14)	V1—V4—O14—V5ⁱ	171.39 (10)
O7—V1—V5—O9	−172.37 (15)	V3—V4—O14—V5ⁱ	87.90 (7)
O6—V1—V5—O9	−93.46 (14)	O11—V4—O14—V2	−6.7 (5)
O14—V1—V5—O9	−176.26 (14)	O8—V4—O14—V2	88.6 (5)
V3—V1—V5—O9	−175.96 (12)	O13ⁱ—V4—O14—V2	−102.2 (5)
V4—V1—V5—O9	129.01 (12)	O12—V4—O14—V2	177.7 (5)
O1—V1—V5—O5	−8.3 (2)	V2ⁱ—V4—O14—V2	−144.0 (5)
O8—V1—V5—O5	91.37 (16)	V1—V4—O14—V2	81.7 (5)
O7—V1—V5—O5	179.98 (17)	V3—V4—O14—V2	−1.8 (5)
O6—V1—V5—O5	−101.11 (16)	O11—V4—O14—V1	−88.40 (9)
O9—V1—V5—O5	−7.64 (18)	O8—V4—O14—V1	6.92 (8)
O14—V1—V5—O5	176.09 (16)	O13ⁱ—V4—O14—V1	176.05 (8)
V3—V1—V5—O5	176.39 (15)	O12—V4—O14—V1	95.93 (8)
V4—V1—V5—O5	121.36 (15)	V2ⁱ—V4—O14—V1	134.29 (5)
O1—V1—V5—O13	99.81 (14)	V3—V4—O14—V1	−83.49 (6)
O8—V1—V5—O13	−160.52 (9)	O11—V4—O14—V3	−4.91 (8)
O7—V1—V5—O13	−71.90 (11)	O8—V4—O14—V3	90.40 (8)
O6—V1—V5—O13	7.01 (9)	O13ⁱ—V4—O14—V3	−100.46 (8)
O9—V1—V5—O13	100.47 (13)	O12—V4—O14—V3	179.42 (8)
O14—V1—V5—O13	−75.79 (9)	V2ⁱ—V4—O14—V3	−142.23 (5)
V3—V1—V5—O13	−75.49 (7)	V1—V4—O14—V3	83.49 (6)
V4—V1—V5—O13	−130.52 (7)	O7—V3—O14—V5ⁱ	−178.61 (9)
O1—V1—V5—O12	−103.93 (14)	O11—V3—O14—V5ⁱ	−84.68 (9)
O8—V1—V5—O12	−4.26 (9)	O10—V3—O14—V5ⁱ	87.17 (9)
O7—V1—V5—O12	84.36 (11)	O5ⁱ—V3—O14—V5ⁱ	1.03 (8)
O6—V1—V5—O12	163.27 (9)	V1—V3—O14—V5ⁱ	−175.74 (9)
O9—V1—V5—O12	−103.27 (13)	V2—V3—O14—V5ⁱ	90.98 (7)
O14—V1—V5—O12	80.47 (9)	V4—V3—O14—V5ⁱ	−89.36 (7)
V3—V1—V5—O12	80.77 (6)	O7—V3—O14—V2	90.41 (9)
V4—V1—V5—O12	25.74 (6)	O11—V3—O14—V2	−175.66 (9)
O1—V1—V5—O14	175.60 (15)	O10—V3—O14—V2	−3.81 (8)
O8—V1—V5—O14	−84.73 (10)	O5ⁱ—V3—O14—V2	−89.95 (8)
O7—V1—V5—O14	3.89 (11)	V1—V3—O14—V2	93.28 (7)
O6—V1—V5—O14	82.80 (10)	V4—V3—O14—V2	179.66 (9)
O9—V1—V5—O14	176.26 (14)	O7—V3—O14—V1	−2.87 (8)
V3—V1—V5—O14	0.30 (7)	O11—V3—O14—V1	91.06 (8)
V4—V1—V5—O14	−54.73 (7)	O10—V3—O14—V1	−97.09 (9)
O1—V1—V5—O14ⁱ	−179.11 (14)	O5ⁱ—V3—O14—V1	176.77 (9)
O8—V1—V5—O14ⁱ	−79.44 (10)	V2—V3—O14—V1	−93.28 (7)
O7—V1—V5—O14ⁱ	9.18 (12)	V4—V3—O14—V1	86.38 (6)
O6—V1—V5—O14ⁱ	88.09 (10)	O7—V3—O14—V4	−89.25 (9)
O9—V1—V5—O14ⁱ	−178.45 (14)	O11—V3—O14—V4	4.68 (8)
O14—V1—V5—O14ⁱ	5.29 (13)	O10—V3—O14—V4	176.53 (9)
V3—V1—V5—O14ⁱ	5.59 (7)	O5ⁱ—V3—O14—V4	90.39 (8)
V4—V1—V5—O14ⁱ	−49.44 (7)	V1—V3—O14—V4	−86.38 (6)
O9—V5—O5—V3ⁱ	−179.31 (11)	V2—V3—O14—V4	−179.66 (9)
O13—V5—O5—V3ⁱ	78.92 (12)	C6—N1—C2—C3	−54.0 (5)
O12—V5—O5—V3ⁱ	−81.01 (12)	N1—C2—C3—C4	55.4 (5)
O14—V5—O5—V3ⁱ	−4.7 (4)	C2—C3—C4—C5	−56.1 (5)
O14ⁱ—V5—O5—V3ⁱ	−1.50 (11)	C3—C4—C5—C6	56.1 (5)
V1—V5—O5—V3ⁱ	−174.18 (5)	C2—N1—C6—C5	53.4 (5)
O2—V2—O6—C1	29.8 (3)	C4—C5—C6—N1	−55.0 (5)
O10—V2—O6—C1	135.2 (3)	C11—N2—C7—C8	−52.4 (5)
O12ⁱ—V2—O6—C1	−115.0 (3)	N2—C7—C8—C9	54.5 (6)
O13—V2—O6—C1	−68.2 (3)	C7—C8—C9—C10	−57.3 (6)
O14—V2—O6—C1	−142.9 (3)	C8—C9—C10—C11	57.9 (6)
V4ⁱ—V2—O6—C1	−66.3 (3)	C7—N2—C11—C10	51.9 (5)
V3—V2—O6—C1	167.7 (3)	C9—C10—C11—N2	−55.4 (5)

Symmetry code: (i) −x+1, −y, −z+1.

Hydrogen-bond geometry (Å, º) top

D—H···A	D—H	H···A	D···A	D—H···A
N1—H1D···O4ⁱⁱ	0.90	2.04	2.887 (4)	157
N1—H1E···O12	0.90	1.90	2.774 (4)	162
N2—H2C···O3ⁱⁱⁱ	0.90	2.53	3.276 (4)	140
N2—H2C···O11ⁱⁱⁱ	0.90	2.34	3.134 (4)	146
N2—H2D···O8	0.90	1.90	2.795 (4)	174

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

Experimental details

Crystal data
Chemical formula	(C₅H₁₂N)₄[V₁₀(CH₃O)₂O₂₆]
M_r	1332.09
Crystal system, space group	Monoclinic, P2₁/n
Temperature (K)	296
a, b, c (Å)	10.546 (2), 12.950 (3), 16.033 (3)
β (°)	90.58 (3)
V (Å³)	2189.5 (8)
Z	2
Radiation type	Mo Kα
µ (mm⁻¹)	2.13
Crystal size (mm)	0.22 × 0.18 × 0.14

Data collection
Diffractometer	Bruker APEX area-detector diffractometer
Absorption correction	Multi-scan SADABS (Sheldrick, 2003)
T_min, T_max	0.639, 0.734
No. of measured, independent and observed [I > 2σ(I)] reflections	11580, 3957, 3226
R_int	0.021
(sin θ/λ)_max (Å⁻¹)	0.600

Refinement
R[F² > 2σ(F²)], wR(F²), S	0.031, 0.093, 1.02
No. of reflections	3957
No. of parameters	290
H-atom treatment	H-atom parameters constrained
Δρ_max, Δρ_min (e Å⁻³)	0.73, −0.45

Computer programs: SMART (Bruker, 2002), SAINT (Bruker, 2002), SAINT, SHELXS97 (Sheldrick, 1997), SHELXL97 (Sheldrick, 1997), XP (Siemens, 1994)), WinGX (Farrugia, 1999).

Selected geometric parameters (Å, º) top

V1—O1	1.600 (2)	V3—O10	1.904 (2)
V1—O6	2.007 (2)	V3—O11	1.893 (2)
V1—O7	1.836 (2)	V3—O14	2.337 (2)
V1—O8	1.810 (2)	V4—O4	1.603 (2)
V1—O9	2.033 (2)	V4—O8	1.893 (2)
V1—O14	2.271 (2)	V4—O11	1.784 (2)
V2—O2	1.598 (2)	V4—O12	2.036 (2)
V2—O6	1.952 (2)	V4—O13ⁱ	1.936 (2)
V2—O10	1.755 (2)	V4—O14	2.288 (2)
V2—O12ⁱ	1.942 (2)	V5—O5	1.689 (2)
V2—O13	2.051 (2)	V5—O9	1.684 (2)
V2—O14	2.242 (2)	V5—O12	1.956 (2)
V3—O3	1.600 (2)	V5—O13	1.903 (2)
V3—O5ⁱ	2.033 (2)	V5—O14	2.072 (2)
V3—O7	1.807 (2)	V5—O14ⁱ	2.163 (2)

C1—O6—V1	122.0 (2)	C1—O6—V2	121.0 (2)