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The cation of the title compound, C13H18N3S+·NO3-, consists of two subunits, viz. a planar indole moiety and a nonplanar thio­uronium moiety. An isolated inter­molecular hydrogen bond connects the cation with the nitrate anion. The crystal packing is additionally characterized by short inter­molecular contacts between parallel indole systems. A topological analysis of the electron density revealed C-S single bonds and partial double bonding in the N-C-N group.

Supporting information

cif

Crystallographic Information File (CIF) https://doi.org/10.1107/S0108270108000668/tr3035sup1.cif
Contains datablocks global, I

hkl

Structure factor file (CIF format) https://doi.org/10.1107/S0108270108000668/tr3035Isup2.hkl
Contains datablock I

CCDC reference: 681565

Comment top

Urea and thiourea derivatives can be efficient metal-free organocatalysts (Takemoto, 2005). In this context, their hydrogen-bonding abilities play a central role in molecular recognitition. We therefore performed crystal structure determinations of the title compound, (I), indole-3-thiouronium nitrate, (II) (Lutz et al., 2008a), and indole-3-thiouronium iodide, (III) (Lutz et al., 2008b). In order to investigate the bonding situation of the tetramethylthiouronium group, a multipole refinement and topological analysis of (I) were performed.

The molecular structure of (I) consist of two parts, viz. a planar indole moiety and a nonplanar thiouronium moiety (Fig. 1). The short C9—N bonds (Table 1) indicate a significant double-bond character, but they are slightly longer than those in the corresponding NH2 compounds (II) and (III) [1.306 (2)–1.317 (2) Å]. The corresponding C—N bond lengths in urea (Zavodnik et al., 1999) and N,N,N',N'-tetramethylurea (Frampton & Parkes, 1996) are 1.343 and 1.3706 (13) Å, respectively. A comparison with the corresponding thiourea derivatives cannnot be considered here, because free thiourea undergoes ferroelectric phase transitions (Takahashi et al., 1990) and the crystal structure of N,N,N',N'-tetramethylthiourea is not available in the literature.

As a result of the tetramethyl substitution of the thiouronium group, the molecule has only one NH hydrogen-bond donor. Atom O1 of the nitrate anion accepts this hydrogen bond to form an isolated cation–anion pair with graph-set descriptor D (Etter, 1990). The NH2 derivatives (II) and (III) have five hydrogen-bond donors and form polymeric two- and three-dimensional networks, respectively. The density of 1.388 Mg m-3 in (I) is consequently lower than the 1.513 Mg m-3 in (II).

The indole ring systems form centrosymmetric, parallel dimers. The intermolecular distance between atom S1(1 - x, 1 - y, 1 - z) and the least-squares plane of the indole ring is 3.43323 (6) Å. Despite this relatively short distance we do not assume π-stacking interactions, because the indole systems are not on top of each other (Fig. 2). The intermolecular distance between the centers of gravity of the five-membered rings is consequently very long [4.5681 (2) Å].

A search of the Cambridge Structural Database (update of August 2007; Allen, 2002) revealed 38 entries containing thiouronium and four entries for N,N,N',N'-tetramethylthiouronium compounds, of which 12 are drawn with an SC9 double bond (e.g. Abashev et al., 1987). 20 entries have a C9N double bond and consequently a positive charge on an N atom (e.g. Garner et al., 1998). Nine entries have the positive charge delocalized over the N—C—N group (e.g. Ishii et al., 2000) and one entry has no indication about the bond order. To investigate the bonding situation of the thiouronium group, we performed a high-resolution diffraction experiment on (I), followed by a multipole refinement of the structure. Deformation densities of the indole system and the environment of atom C9 are shown in Fig. 3.

A topological analysis of the cation shows that the Laplacians at the bond critical points of the C9—N bonds have the highest magnitudes, of -26.33 (7) and -26.02 (7) e Å-5, respectively (Table 3). Because the Laplacian at the bond critical point is a measure of the bond strength (Bader, 1990), this analysis clearly shows that these are the strongest bonds in the cations. The negative sign of the values indicates covalent bonding. A quantum-chemical study of urea (Gatti et al., 1994) gives a value of -1.15 a.u. (corresponding to -27.71 e Å-5) for the Laplacian at the bond critical point of the C—N single bond. In an experimental study of urea (Zavodnik et al., 1999), a value of -27.34 e Å-5 was determined. We can therefore conclude that the bond strengths of the C—N bonds in (I) and in urea are very similar.

The Laplacians at the bond critical points of the C—S bonds of -4.918 (19) and -5.008 (19) e Å-5 are very similar to the C—S single bonds of the dipeptide DL-alanylmethionine, with values of -4.9 and -4.7 e Å-5 (Guillot et al., 2001). The bond order of the C—S bonds in (I) is thus best described as a single bond.

The net charges of the atoms (Table 4) derived from the monopole populations indicate a negative charge concentration on the C atoms of the four methyl groups. As expected, the positive charges are distributed over the H atoms. Adding these charges gives a negative charge of -0.51 for the nitrate anion and, because of the applied electroneutrality constraint, +0.51 for the cation.

A thermal motion analysis using the program THMA11 (Schomaker & Trueblood, 1998) results in a low weighted R value {R = [Σ(wΔU)2/Σ(wUobs)2]1/2} of 0.093, indicating that the molecule behaves as a rigid body in the solid state at 110 K. This value can be decreased if the thiouronium moiety is treated as an independent rigid body with the S1—C9 bond as rotation axis, resulting in R = 0.065. This analysis additionally supports the description of S1—C9 as a single bond allowing free rotation.

Related literature top

For related literature, see: Abashev et al. (1987); Allen (2002); Bader (1990); Etter (1990); Frampton & Parkes (1996); Garner et al. (1998); Gatti et al. (1994); Guillot et al. (2001); Hirshfeld (1976); Ishii et al. (2000); Koritsanszky et al. (2003); Lutz et al. (2008a, 2008b); Macchi (2000); Schomaker & Trueblood (1998); Sheldrick (2008); Stewart et al. (1975); Takahashi et al. (1990); Takemoto (2005); Zavodnik et al. (1999).

Experimental top

For the preparation of indole-3-N,N,N',N'-tetramethylthiouronium iodide, to a solution of indole (0.600 g, 5.12 mmol) and N,N,N',N'-tetramethylthiourea (0.677 g, 5.12 mmol) in a 4:1 (v/v) mixture of MeOH and H2O (20 ml) were added I2 (1.30 g, 5.12 mmol) and KI (0.850 g, 5.12 mmol). The mixture was stirred overnight and then evaporated to dryness. The residue was washed with water and ether, yielding a dark-yellow powder (yield 1.67 g, 4.45 mmol, 87%). Analysis calculated for C13H18IN3S: C 41.61, H 4.83, N 11.20, S 8.54%; found: C 41.53, H 4.78, N 11.15, S 8.65%. 1H NMR (DMSO-d6): δ 12.00 (s, br, 1H, NH), 7.99 (d, 3JH—H = 2.7 Hz, 1H, indolyl 2-H), 7.53 (d, 3JH—H = 7.9 Hz, 1H, indolyl H), 7.43 (d, 3JH—H = 7.9 Hz, 1H, indolyl H), 7.26 (td, 3JH—H = 7.6 Hz, 4JH—H = 1.2 Hz, 1H, indolyl H), 7.18 (t, 3JH—H = 7.4 Hz, 1H, indolyl H), 3.14 (s, 12H, CH3). 13C{1H} NMR (DMSO-d6): δ 174.76 [C(NMe2)2], 136.25, 132.65, 126.97, 122.77, 121.02, 117.28, 112.75, 94.54 (8 × indolyl C), 43.58 (CH3). FT–IR (ATR, ν, cm-1): 3136, 3099, 1600, 1498, 1455, 1413, 1380, 1340, 1256, 1235, 1166, 1100, 1006, 874, 758, 751, 691.

For the preparation of indole-3-N,N,N',N'-tetramethylthiouronium nitrate, to a solution of AgNO3 (0.0453 g, 0.266 mmol) in EtOH (10 ml) was added indole-3-N,N,N',N'-tetramethylthiouronium iodide (0.100 g, 0.266 mmol). The mixture was refluxed for 1 h and then filtered to remove AgCl. The resulting cream-colored solution was concentrated in vacuo. Ether was added overnight by vapor diffusion. Colorless crystals formed, which proved to be suitable for X-ray diffraction studies. The crystals remaining after X-ray analysis were filtered off, washed with ether and dried in vacuo (yield 0.0667 g, 2.15 mmol, 81%). Analysis calculated for C13H18N4O3S: C 50.31, H 5.85, N 18.05, S 10.33%; found: C 50.46, H 5.80, N 18.15, S 10.25%. The 1H NMR spectrum was identical to that of the starting compound. FT–IR (ATR, ν, cm-1): 3100, 2927, 1599, 1502, 1456, 1362, 1324, 1256, 1238, 1208, 1166, 1112, 1101, 1059, 1042, 1009, 876, 830, 784, 760, 748.

Refinement top

The initial refinement was performed with a spherical atom model using the program SHELXL97 (Sheldrick, 2008) on F2 of all reflections. H atoms were refined freely with isotropic displacement parameters.

The results of the SHELXL97 refinement were then transferred to the program XD (Koritsanszky et al., 2003). After a spherical atom refinement, the H atoms were fixed and a spherical atom refinement of the non-H atoms was performed on data with sinθ/λ larger than 0.7 Å-1. In the following step, the non-H atoms were fixed and the positions and isotropic displacement parameters of the H atoms were refined on data with sinθ/λ smaller than 0.7 Å-1. A polarized density function with a bond-directed dipole was used here for the H atoms. The polarized H atom was introduced by Stewart et al. (1975) and adapted to the XD package by Macchi (2000).

In a final refinement, the positions and displacement parameters of the H atoms were fixed and non-H atoms were refined anisotropically. Multipole parameters were also refined in this step, for S atoms up to the hexadecapole level, and for C, N and O atoms up to the octopole level. For H atoms, a mononople and a dipole in bond direction was refined. The refinement was performed on F of reflections with F > 2σ(F). The weights in the least squares refinement were 1/σ2. 93.7% of the reflections were measured six or more times for useful merged σ values. Residual electron densities of the spherical atom refinement and the multipole refinement are given in Fig. 4.

The largest differences of mean-squares displacement amplitudes in the direction of the bonds (Hirshfeld, 1976) are 0.0014 (2) Å2 for N4—O2 in the anion and 0.0012 (2) Å2 for N2—C10 in the cation. The largest peaks and holes of the difference electron density map are close to atom O3 of the nitrate anion, with distances of 0.52 and 0.50 Å, respectively.

Computing details top

Data collection: COLLECT (Nonius, 1999); cell refinement: PEAKREF (Schreurs, 2005); data reduction: EVAL15 (Xian et al., 2006) and SADABS (Sheldrick, 2006); program(s) used to solve structure: SHELXS97 (Sheldrick, 2008); program(s) used to refine structure: XD (Koritsanszky et al., 2003); molecular graphics: XD (Koritsanszky et al., 2003) and PLATON (Spek, 2003); software used to prepare material for publication: XD (Koritsanszky et al., 2003).

Figures top
[Figure 1] Fig. 1. : Molecular structure of (I) after multipole refinement. Displacement ellipsoids are drawn at the 50% probability level and H atoms are shown as small spheres of arbitrary radii. The N—H···O hydrogen bond is drawn with a dashed line.
[Figure 2] Fig. 2. : Centrosymmetric dimer of the indole systems. View along the crystallographic [1,1,0] direction. Hydrogen atoms and nitrate anions are omitted for clarity. Symmetry operation i: 1 - x, 1 - y, 1 - z.
[Figure 3] Fig. 3. : Deformation density in the plane of the indole system (left) and the planar environment of C9 (right). Contour lines correspond to 0.1 e Å-3. Positive values are drawn as solid lines in green, negative values as dashed lines in red, and the zero level as dotted lines in black.
[Figure 4] Fig. 4. : Residual density in the plane of the indole system after spherical atom refinement (left) and after multipole refinement (right). Contour lines correspond to 0.1 e Å-3. Positive values are drawn as solid lines in green, negative values as dashed lines in red. The zero level is omitted for clarity.
2-(indol-3-yl)-1,1,3,3-tetramethylthiouronium nitrate top
Crystal data top
C13H18N3S+·NO3F(000) = 1312
Mr = 310.37Dx = 1.388 Mg m3
Orthorhombic, PbcaMo Kα radiation, λ = 0.71073 Å
Hall symbol: -P 2ac 2abCell parameters from 43746 reflections
a = 12.46443 (1) Åθ = 1.9–45.0°
b = 11.02991 (7) ŵ = 0.23 mm1
c = 21.60929 (4) ÅT = 110 K
V = 2970.88 (2) Å3Block, colourless
Z = 80.36 × 0.24 × 0.24 mm
Data collection top
Nonius KappaCCD
diffractometer
9924 reflections with I > 2σ(I)
ϕ and ω scansRint = 0.034
Absorption correction: multi-scan
(SADABS; Sheldrick, 2006)
θmax = 45.0°
Tmin = 0.744, Tmax = 0.943h = 2424
247693 measured reflectionsk = 2121
12242 independent reflectionsl = 4242
Refinement top
Refinement on F0 restraints
Least-squares matrix: fullH-atom parameters constrained
R[F2 > 2σ(F2)] = 0.020 w1 = 1/[s2(Fo)]
wR(F2) = 0.011(Δ/σ)max < 0.001
S = 2.03Δρmax = 0.34 e Å3
9926 reflectionsΔρmin = 0.29 e Å3
570 parameters
Crystal data top
C13H18N3S+·NO3V = 2970.88 (2) Å3
Mr = 310.37Z = 8
Orthorhombic, PbcaMo Kα radiation
a = 12.46443 (1) ŵ = 0.23 mm1
b = 11.02991 (7) ÅT = 110 K
c = 21.60929 (4) Å0.36 × 0.24 × 0.24 mm
Data collection top
Nonius KappaCCD
diffractometer
12242 independent reflections
Absorption correction: multi-scan
(SADABS; Sheldrick, 2006)
9924 reflections with I > 2σ(I)
Tmin = 0.744, Tmax = 0.943Rint = 0.034
247693 measured reflections
Refinement top
R[F2 > 2σ(F2)] = 0.0200 restraints
wR(F2) = 0.011H-atom parameters constrained
S = 2.03Δρmax = 0.34 e Å3
9926 reflectionsΔρmin = 0.29 e Å3
570 parameters
Special details top

Experimental. All frames were collected with a rotation angle of 1°. 364 (ϕ) and 453 frames (ω) had an exposure time of 20 s. 364 frames (ϕ) had an exposure time of 4 s. 220 frames (ω) had an exposure time of 100 s. 935 frames (ω) had an exposure time of 150 s.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
S10.585023 (5)0.513021 (6)0.597567 (3)0.015
O10.85945 (5)0.42997 (7)0.34113 (2)0.033
O20.85897 (6)0.41030 (6)0.24132 (2)0.032
O30.76206 (6)0.29172 (7)0.29729 (3)0.035
N10.71393 (3)0.39633 (4)0.442256 (16)0.016
N20.50667 (3)0.39070 (3)0.692843 (15)0.015
N30.65585 (3)0.30190 (3)0.647822 (15)0.015
N40.82637 (3)0.37762 (4)0.293055 (18)0.017
C10.70568 (3)0.47639 (3)0.490549 (15)0.016
C20.62468 (3)0.43963 (3)0.529776 (13)0.014
C30.49521 (3)0.25383 (3)0.521848 (15)0.016
C40.47373 (3)0.15363 (4)0.485154 (17)0.019
C50.53437 (3)0.12892 (4)0.431485 (16)0.019
C60.61733 (3)0.20431 (3)0.412873 (14)0.016
C70.63867 (2)0.30598 (3)0.449793 (13)0.013
C80.57935 (2)0.33104 (3)0.504170 (13)0.013
C90.58384 (2)0.39142 (3)0.650401 (12)0.012
C100.41015 (3)0.46528 (4)0.688203 (18)0.023
C110.52470 (3)0.33796 (4)0.754327 (15)0.020
C120.62720 (3)0.17585 (3)0.661155 (18)0.020
C130.76534 (3)0.31836 (4)0.625531 (18)0.020
H10.765320.403750.407390.037
H20.755060.554650.494070.021
H30.447490.271220.561930.023
H40.411800.094380.497400.024
H50.516990.050150.404790.026
H60.664610.188220.372090.022
H70.344290.418920.711860.034
H80.421070.553550.708840.040
H90.384620.474550.640260.035
H100.470860.262350.762080.024
H110.510270.409790.787160.024
H120.604880.308610.759410.022
H130.668360.141990.700630.028
H140.650670.121310.620370.025
H150.541090.166200.668140.022
H160.786300.413980.624870.021
H170.775660.281430.579860.028
H180.819910.271950.656510.030
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
S10.02199 (3)0.01192 (2)0.01145 (2)0.00257 (2)0.00118 (2)0.00074 (2)
O10.0324 (2)0.0494 (3)0.01675 (19)0.0197 (2)0.00656 (17)0.0094 (2)
O20.0455 (3)0.0338 (3)0.01623 (18)0.0166 (2)0.00793 (19)0.00173 (17)
O30.0413 (3)0.0386 (3)0.0239 (2)0.0227 (3)0.0010 (2)0.0026 (2)
N10.01562 (12)0.02088 (15)0.01103 (11)0.00073 (12)0.00253 (10)0.00176 (11)
N20.01591 (12)0.01737 (13)0.01071 (11)0.00155 (11)0.00046 (10)0.00056 (10)
N30.01528 (12)0.01361 (12)0.01461 (12)0.00191 (11)0.00017 (10)0.00201 (10)
N40.01674 (13)0.02013 (16)0.01341 (14)0.00248 (12)0.00301 (11)0.00085 (12)
C10.01722 (12)0.01748 (13)0.01277 (11)0.00200 (11)0.00122 (10)0.00249 (10)
C20.01617 (11)0.01470 (12)0.01016 (10)0.00044 (10)0.00110 (9)0.00082 (9)
C30.01553 (12)0.01940 (14)0.01297 (11)0.00184 (11)0.00258 (10)0.00065 (10)
C40.01854 (13)0.02116 (15)0.01693 (13)0.00443 (12)0.00150 (11)0.00208 (12)
C50.02045 (14)0.02076 (15)0.01530 (13)0.00163 (12)0.00010 (11)0.00359 (11)
C60.01798 (12)0.02045 (14)0.01098 (11)0.00144 (12)0.00079 (10)0.00213 (10)
C70.01369 (11)0.01694 (12)0.00974 (10)0.00122 (10)0.00067 (9)0.00068 (9)
C80.01333 (10)0.01529 (11)0.00973 (10)0.00060 (10)0.00099 (9)0.00071 (9)
C90.01469 (10)0.01278 (11)0.00995 (10)0.00095 (10)0.00028 (9)0.00033 (8)
C100.01995 (14)0.02767 (18)0.02065 (15)0.00707 (14)0.00415 (12)0.00228 (13)
C110.02355 (15)0.02321 (15)0.01176 (12)0.00103 (13)0.00113 (10)0.00261 (11)
C120.02417 (15)0.01417 (13)0.02154 (14)0.00154 (12)0.00081 (12)0.00264 (11)
C130.01565 (12)0.02285 (16)0.02275 (15)0.00335 (12)0.00078 (11)0.00424 (12)
Geometric parameters (Å, º) top
S1—C21.7452 (3)C4—C51.4109 (5)
S1—C91.7614 (3)C4—H41.05
O1—N41.2580 (6)C5—C61.3866 (5)
O2—N41.2429 (5)C5—H51.07
O3—N41.2444 (6)C6—C71.4017 (5)
N1—C11.3709 (5)C6—H61.08
N1—C71.3783 (5)C7—C81.4156 (4)
N1—H10.99C10—H71.09
N2—C91.3291 (4)C10—H81.08
N2—C101.4608 (5)C10—H91.09
N2—C111.4677 (4)C11—H101.08
N3—C91.3355 (4)C11—H111.08
N3—C121.4641 (5)C11—H121.06
N3—C131.4586 (5)C12—H131.06
C1—C21.3792 (4)C12—H141.11
C1—H21.06C12—H151.09
C2—C81.4353 (4)C13—H161.09
C3—C41.3863 (5)C13—H171.08
C3—C81.4039 (4)C13—H181.08
C3—H31.07
C2—S1—C9101.142 (14)N1—C7—C8108.20 (3)
C1—N1—C7108.95 (3)C6—C7—C8121.98 (3)
C1—N1—H1125.0C2—C8—C3134.06 (3)
C7—N1—H1126.1C2—C8—C7106.10 (3)
C9—N2—C10123.05 (3)C3—C8—C7119.84 (3)
C9—N2—C11121.08 (3)S1—C9—N2117.25 (3)
C10—N2—C11114.29 (3)S1—C9—N3122.03 (2)
C9—N3—C12122.00 (3)N2—C9—N3120.72 (3)
C9—N3—C13123.41 (3)N2—C10—H7108.8
C12—N3—C13114.29 (3)N2—C10—H8112.1
O1—N4—O2120.17 (5)N2—C10—H9111.0
O1—N4—O3119.99 (5)H7—C10—H8108.9
O2—N4—O3119.83 (5)H7—C10—H9105.6
N1—C1—C2109.48 (3)H8—C10—H9110.2
N1—C1—H2122.3N2—C11—H10110.5
C2—C1—H2128.2N2—C11—H11106.2
S1—C2—C1125.94 (3)N2—C11—H12111.1
S1—C2—C8126.81 (2)H10—C11—H11111.1
C1—C2—C8107.25 (3)H10—C11—H12109.5
C4—C3—C8118.18 (3)H11—C11—H12108.3
C4—C3—H3120.0N3—C12—H13112.0
C8—C3—H3121.9N3—C12—H14107.2
C3—C4—C5121.38 (3)N3—C12—H15111.1
C3—C4—H4119.7H13—C12—H14108.7
C5—C4—H4118.9H13—C12—H15109.3
C4—C5—C6121.48 (3)H14—C12—H15108.5
C4—C5—H5119.6N3—C13—H16110.5
C6—C5—H5118.9N3—C13—H17111.6
C5—C6—C7117.14 (3)N3—C13—H18109.0
C5—C6—H6123.2H16—C13—H17109.1
C7—C6—H6119.7H16—C13—H18108.4
N1—C7—C6129.82 (3)H17—C13—H18108.3
C9—S1—C2—C1130.40 (3)N1—C1—C2—C80.49 (4)
C9—S1—C2—C850.03 (3)S1—C2—C8—C30.90 (5)
C2—S1—C9—N2142.61 (3)S1—C2—C8—C7179.21 (2)
C2—S1—C9—N336.25 (3)C1—C2—C8—C3178.74 (4)
C7—N1—C1—C20.40 (4)C1—C2—C8—C71.15 (4)
C1—N1—C7—C6179.36 (3)C8—C3—C4—C50.12 (5)
C1—N1—C7—C81.13 (4)C4—C3—C8—C2179.46 (4)
C10—N2—C9—S116.08 (5)C4—C3—C8—C70.67 (5)
C10—N2—C9—N3162.79 (3)C3—C4—C5—C60.58 (6)
C11—N2—C9—S1148.75 (3)C4—C5—C6—C70.22 (5)
C11—N2—C9—N332.38 (5)C5—C6—C7—N1178.87 (4)
C12—N3—C9—S1142.67 (3)C5—C6—C7—C80.58 (5)
C12—N3—C9—N236.16 (5)N1—C7—C8—C21.40 (3)
C13—N3—C9—S130.69 (5)N1—C7—C8—C3178.51 (3)
C13—N3—C9—N2150.49 (3)C6—C7—C8—C2179.05 (3)
N1—C1—C2—S1179.87 (3)C6—C7—C8—C31.04 (5)
Hydrogen-bond geometry (Å, º) top
D—H···AD—HH···AD···AD—H···A
N1—H1···O10.991.872.8642 (7)176

Experimental details

Crystal data
Chemical formulaC13H18N3S+·NO3
Mr310.37
Crystal system, space groupOrthorhombic, Pbca
Temperature (K)110
a, b, c (Å)12.46443 (1), 11.02991 (7), 21.60929 (4)
V3)2970.88 (2)
Z8
Radiation typeMo Kα
µ (mm1)0.23
Crystal size (mm)0.36 × 0.24 × 0.24
Data collection
DiffractometerNonius KappaCCD
diffractometer
Absorption correctionMulti-scan
(SADABS; Sheldrick, 2006)
Tmin, Tmax0.744, 0.943
No. of measured, independent and
observed [I > 2σ(I)] reflections
247693, 12242, 9924
Rint0.034
(sin θ/λ)max1)0.995
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.020, 0.011, 2.03
No. of reflections9926
No. of parameters570
H-atom treatmentH-atom parameters constrained
Δρmax, Δρmin (e Å3)0.34, 0.29

Computer programs: COLLECT (Nonius, 1999), PEAKREF (Schreurs, 2005), EVAL15 (Xian et al., 2006) and SADABS (Sheldrick, 2006), SHELXS97 (Sheldrick, 2008), XD (Koritsanszky et al., 2003) and PLATON (Spek, 2003).

Selected geometric parameters (Å, º) top
S1—C21.7452 (3)N2—C91.3291 (4)
S1—C91.7614 (3)N3—C91.3355 (4)
C2—S1—C9101.142 (14)S1—C9—N3122.03 (2)
S1—C9—N2117.25 (3)N2—C9—N3120.72 (3)
C2—S1—C9—N2142.61 (3)C11—N2—C9—S1148.75 (3)
C2—S1—C9—N336.25 (3)C12—N3—C9—S1142.67 (3)
C10—N2—C9—S116.08 (5)C13—N3—C9—S130.69 (5)
Hydrogen-bond geometry (Å, º) top
D—H···AD—HH···AD···AD—H···A
N1—H1···O10.991.872.8642 (7)176
Topological characteristics of the electron density in the cation of (I) top
Bondd(Å)d1(Å)d2(Å)ρ(eÅ-3)ellipticitydel2f(eÅ-5)
S1-C21.74550.88610.85931.334 (8)0.13-4.202 (14)
S1-C91.76180.87480.88701.320 (8)0.24-3.818 (14)
N1-C11.37080.81620.55472.17 (2)0.16-21.15 (9)
N1-C71.37890.78920.58972.193 (18)0.20-19.76 (7)
N2-C91.32910.76850.56062.490 (18)0.25-26.93 (8)
N2-C101.46090.86300.59791.738 (19)0.07-11.60 (6)
N2-C111.46840.85510.61331.662 (16)0.03-8.87 (5)
N3-C91.33550.77380.56172.442 (18)0.22-26.12 (8)
N3-C121.46460.85240.61221.694 (18)0.10-9.74 (6)
N3-C131.45870.86900.58971.693 (18)0.04-10.84 (6)
C1-C21.37990.71890.66102.214 (14)0.31-19.60 (4)
C2-C81.43720.71760.71961.966 (13)0.18-14.80 (3)
C3-C41.38620.70340.68292.198 (15)0.22-19.98 (4)
C3-C81.40420.67690.72732.109 (14)0.21-18.67 (4)
C4-C51.41110.70360.70752.078 (14)0.21-17.75 (4)
C5-C61.38670.72300.66362.171 (16)0.21-19.25 (4)
C6-C71.40250.66650.73602.114 (15)0.23-18.74 (4)
C7-C81.41580.72060.69522.106 (13)0.21-18.32 (3)
Net atomic charges derived from the monopole populations top
S1-0.123
O1-0.214
O2-0.142
O3-0.174
N1-0.097
N2-0.128
N3-0.136
N4+0.025
C1-0.149
C2-0.173
C3-0.143
C4-0.127
C5-0.160
C6-0.112
C7-0.109
C8-0.102
C9-0.112
C10-0.300
C11-0.389
C12-0.251
C13-0.244
H1+0.241
H2+0.224
H3+0.177
H4+0.161
H5+0.147
H6+0.192
H7+0.181
H8+0.153
H9+0.166
H10+0.169
H11+0.171
H12+0.189
H13+0.206
H14+0.203
H15+0.214
H16+0.238
H17+0.167
H18+0.162
 

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