Buy article online - an online subscription or single-article purchase is required to access this article.
Download citation
Download citation
link to html
In order to investigate the effect of counter-anions on the polymeric structure of (2,2-dimethyl­propane-1,3-diyl diiso­cyanide)silver(I) complexes, the novel title polymeric compound, [Ag(NO3)(C7H10N2)]n, has been synthesized. The crystal structure was determined by simulated annealing from X-ray powder diffraction data collected at room temperature. The current structure is similar to the recently reported structure of the analogue with chloride replacing nitrate. This study illustrates that both the chloride and nitrate complexes crystallize in the orthorhombic system in the Pbca space group with one monomer in the asymmetric unit, and also gives a strong indication that the counter-anion does not have a considerable effect on the polymeric structure of the complex. The Ag centre lies in a distorted tetra­hedral environment and is bonded to two 2,2-dimethyl­propane-1,3-diyl diiso­cyanide ligands to form chains. The nitrate anions crosslink the Ag centres of the chains to form a two-dimensional polymeric network structure.

Supporting information

cif

Crystallographic Information File (CIF) https://doi.org/10.1107/S0108270108005143/sk3191sup1.cif
Contains datablocks global, I

rtv

Rietveld powder data file (CIF format) https://doi.org/10.1107/S0108270108005143/sk3191Isup2.rtv
Contains datablock I

CCDC reference: 686420

Comment top

Diisocyanides are of considerable current interest as bidentate ligands in coordination chemistry (Harvey, 2001; Sakata et al., 2003; Espinet et al., 2000; Moigno et al., 2002). Some diisocyanides have been used in the synthesis of bi-, tri- and tetranuclear complexes and organometallic polymers, which have potential practical applications as new materials in the areas of hydrogen gas production (Mann et al., 1977; Sigal et al.,1980), and semi- and photoconductivity (Fortin et al., 2000). Very recently, we reported the synthesis and solid-state structure of the organometallic polymer {[AgCNCH2C(CH3)2CH2NC]Cl}n (Al-Ktaifani et al., 2008), which was prepared by treatment of CNCH2C(CH3)2CH2NC with AgCl. Since we are currently interested in the synthesis of new metal complexes using the bidentate CNCH2C(CH3)2CH2NC ligand, it would be interesting to examine how changing the counteranion might affect the structure and properties of the product obtained. Therefore, the title compound, (I), which is a highly insoluble light-yellow powder, was prepared by treatment of CNCH2C(CH3)2CH2NC with AgNO3. In the present work, we employed laboratory X-ray powder diffraction to solve and refine the crystal structure of this polymeric compound.

The present study reveals a polymeric structure, in which the Ag centres are bridged to each of the two adjacent Ag neighbours by bidentate CNCH2C(CH3)2CH2NC ligands via the NC groups, at distances of 2.092 (8) and 2.104 (8) Å, to form {Ag(CNCH2C(CH3)2CH2NC)}n chains. The NO3 counteranions crosslink the Ag centres of the chains, each via two O atoms at distances of 2.597 (4) and 2.538 (5) Å, to form a polymeric two-dimensional {[Ag(CNCH2C(CH3)2CH2NC)]NO3}n network (Fig. 1). The distances between the Ag centre and the C atom (C N–) of the ligand and the O atom of NO3 were restrained in the Rietveld refinement. The polymeric structure of (I) shows that the CNCH2C(CH3)2CH2NC ligand in the complex behaves only in a bis-monodentate manner, while chelate behaviour is completely absent. This is undoubtedly expected for steric reasons, as the distance between the two isocyanide groups in the CNCH2C(CH3)2CH2NC molecule are too short to allow chelate complexing (Chemin et al., 1996) (Fig. 2).

In the title complex, the C—C bond distances are 1.566 (11), 1.496 (12), 1.487 (11) and 1.574 (11) Å (average 1.531 Å). The CN [1.136 (11) and 1.134 (10) Å] and N—C [1.452 (10) and 1.457 (10) Å] bond lengths are in their normal ranges [Reference?] and comparable with their counterparts in the reported polymeric structures of {[AgCNCH2C(CH3)2CH2NC]Cl}n (Al-Ktaifani et al., 2008) and {[Ag(dmb)2]NO3·0.7H2O}n (dmb is 1,8-diisocyano-p-menthan; Fortin et al., 1997), and the dinuclear complexes Ag(dmb)2X2 (X = Cl, Br or I; Perreault et al., 1993). These distances were restrained to their normal values in the Rietveld refinement. In each Ag(CNCH2C(CH3)2CH2NC)Ag unit of the polymer, the two Ag—CN angles are almost linear [169.3 (7) and 174.6 (7)°]. Excluding H···H contacts, four short contacts (less than the sum of the van der Waals radii) exist. These are: C4···N3 [2.913 (12) Å], C5···N3 [2.960 (2) Å], C5···N2 [3.000 (14) Å] and C6···N2 [2.928 (10) Å]. Two short contacts are also observed between neighbouring monomers for C1···O2(x, 1/2 - y, 1/2 + z) [2.988 (6) Å] and Ag1···O1(x, 1/2 - y, 1/2 + z) [3.047 (10) Å].

Comparing the average C—C (1.531 Å), Ag—C (2.098 Å), NC (1.135 Å) and N—C (1.455 Å) bond distances and average Ag—C—N (172.0°) and C—Ag—C (159.9°) bond angles of {Ag(I)[CNCH2C(CH3)2CH2NC]NO3}n with their analogous bond distances [average C—C (1.548 Å), Ag—C (2.116 Å), NC (1.160 Å), N—C (1.480 Å)] and angles [average Ag—C—N (164.0°) and C—Ag—C (159.9°)] in {Ag(I)[CNCH2C(CH3)2CH2NC]Cl}n, although the conformations of the bidentate CNCH2C(CH3)2CH2NC ligand in both polymeric strucures are almost alike, it can be concluded that both molecular structures are very similar. Thus, the counteranion (NO3 or Cl) plays no effective role in changing the polymeric structure of the complex.

Related literature top

For related literature, see: Al-Ktaifani, Rukiah & Shaaban (2008); Boultif & Louër (2004); Chemin et al. (1996); Espinet et al. (2000); Favre-Nicolin & Černý (2002); Finger et al. (1994); Fortin et al. (1997, 2000); Harvey (2001); Laugier & Bochu (2001); Mann et al. (1977); Moigno et al. (2002); Perreault et al. (1993); Petříček et al. (2000); Sakata et al. (2003); Sigal et al. (1980).

Experimental top

All reactions and manipulations were carried out under an inert atmosphere using a twofold vacuum line and Schlenk techniques. Solvents were dried and distilled over sodium wire. Glassware was dried and flamed before use. AgNO3 was a commercial sample [Company?] and was used as received. To a suspension of AgNO3 (0.12 g, 0.71 mmol) in dry EtOH (15 ml) was added dropwise a solution of CNCH2C(CH3)2CH2NC (0.17 g, 1.39 mmol) in EtOH (Volume?) with rapid stirring at room temperature. The resulting solution was stirred for 1 h, filtered, and volatiles were removed in vacuo. The resulting product was washed with ether to afford a light-yellow powder [0.24 g, yield 90%, m.p. 441 K (starts to decompose)]. Analytical data for AgC7H10N3O3: found: C 28.60, H 3.77, N 14.62%; required: C 28.78, H 3.45, N 14.38%. IR (KBr) ν cm-1: 2200.3 (NC).

Refinement top

The powder sample was ground lightly in a mortar, loaded between two Mylar foils and fixed in the sample holder with a mask of suitable internal diameter. Data were collected at room temperature and pressure in transmission geometry employing Cu Kα1 radiation. The pattern was indexed using the program DICVOL04 (Boultif & Louër, 2004). An orthorhombic unit cell of reasonable volume (assuming Z = 8) gave indexing figures of merit M20 = 30.9 and F20 = 79.0 (0.0054, 47). The best estimated space group in the orthorhombic system was Pbca, which was determined with the help of the program CHEKCELL (Laugier & Bochu, 2001). The program FOX (Favre-Nicolin & Černý, 2002) was employed for structure solution. The powder pattern was truncated to 35.3° in 2θ (Cu Kα1), corresponding to a real-space resolution of 2.54 Å. Monte Carlo simulated annealing (parallel tempering algorithm) was used to solve the crystal structure of (I) from the powder pattern in direct space. One molecule of the CNCH2C(CH3)2CH2NC ligand, one molecule of the nitrate anion and one free Ag atom were introduced randomly in the orthorhombic cell calculated by Le Bail refinement. The H atoms can be ignored during the structure solution process because they do not contribute significantly to the powder diffraction pattern, due to their low X-ray scattering power. During the parallel tempering calculations, the ligand was allowed to translate, to rotate around its centre of mass and to modify its torsion angles, the nitrate anion was only allowed to translate, and the atom Ag was allowed to modify its position in the unit cell. The model found by FOX was introduced into the program JANA2000 (Petříček et al., 2000) for Rietveld refinement. The effect of the asymmetry of some low-order peaks was corrected using a pseudo-Voigt description of the peak shape which allows for angle-dependent asymmetry with axial divergence (Finger et al., 1994), restricted by the equation H/L = S/L [variables need defining]. Geometric soft restraints were applied to the Ag—C, Ag—O, CN, N—C and C—C distances and to O—N—O angles to their normal values. H atoms were introduced in their theoretical positions, with CH2 and CH3 distances constrained to be 0.97 Å for CH3 and 0.98 Å for CH2. They were refined as riding on their carrier atoms. The atomic displacement parameters for C and N atoms were assigned isotropic. The final refinement cycles were performed using anisotropic displacement parameters for Ag and O atoms. H atoms were assigned constant isotropic displacement parameters of 1.2 times those of their carrier atoms. No preferred orientation was applied to the final refinement. The observed and calculated diffraction patterns for the refined crystal structure are shown in Fig. 3 (χ2= 1.61, Rexp = 0.029, Rp = 0.028 and Rwp = 0.036).

Structure description top

Diisocyanides are of considerable current interest as bidentate ligands in coordination chemistry (Harvey, 2001; Sakata et al., 2003; Espinet et al., 2000; Moigno et al., 2002). Some diisocyanides have been used in the synthesis of bi-, tri- and tetranuclear complexes and organometallic polymers, which have potential practical applications as new materials in the areas of hydrogen gas production (Mann et al., 1977; Sigal et al.,1980), and semi- and photoconductivity (Fortin et al., 2000). Very recently, we reported the synthesis and solid-state structure of the organometallic polymer {[AgCNCH2C(CH3)2CH2NC]Cl}n (Al-Ktaifani et al., 2008), which was prepared by treatment of CNCH2C(CH3)2CH2NC with AgCl. Since we are currently interested in the synthesis of new metal complexes using the bidentate CNCH2C(CH3)2CH2NC ligand, it would be interesting to examine how changing the counteranion might affect the structure and properties of the product obtained. Therefore, the title compound, (I), which is a highly insoluble light-yellow powder, was prepared by treatment of CNCH2C(CH3)2CH2NC with AgNO3. In the present work, we employed laboratory X-ray powder diffraction to solve and refine the crystal structure of this polymeric compound.

The present study reveals a polymeric structure, in which the Ag centres are bridged to each of the two adjacent Ag neighbours by bidentate CNCH2C(CH3)2CH2NC ligands via the NC groups, at distances of 2.092 (8) and 2.104 (8) Å, to form {Ag(CNCH2C(CH3)2CH2NC)}n chains. The NO3 counteranions crosslink the Ag centres of the chains, each via two O atoms at distances of 2.597 (4) and 2.538 (5) Å, to form a polymeric two-dimensional {[Ag(CNCH2C(CH3)2CH2NC)]NO3}n network (Fig. 1). The distances between the Ag centre and the C atom (C N–) of the ligand and the O atom of NO3 were restrained in the Rietveld refinement. The polymeric structure of (I) shows that the CNCH2C(CH3)2CH2NC ligand in the complex behaves only in a bis-monodentate manner, while chelate behaviour is completely absent. This is undoubtedly expected for steric reasons, as the distance between the two isocyanide groups in the CNCH2C(CH3)2CH2NC molecule are too short to allow chelate complexing (Chemin et al., 1996) (Fig. 2).

In the title complex, the C—C bond distances are 1.566 (11), 1.496 (12), 1.487 (11) and 1.574 (11) Å (average 1.531 Å). The CN [1.136 (11) and 1.134 (10) Å] and N—C [1.452 (10) and 1.457 (10) Å] bond lengths are in their normal ranges [Reference?] and comparable with their counterparts in the reported polymeric structures of {[AgCNCH2C(CH3)2CH2NC]Cl}n (Al-Ktaifani et al., 2008) and {[Ag(dmb)2]NO3·0.7H2O}n (dmb is 1,8-diisocyano-p-menthan; Fortin et al., 1997), and the dinuclear complexes Ag(dmb)2X2 (X = Cl, Br or I; Perreault et al., 1993). These distances were restrained to their normal values in the Rietveld refinement. In each Ag(CNCH2C(CH3)2CH2NC)Ag unit of the polymer, the two Ag—CN angles are almost linear [169.3 (7) and 174.6 (7)°]. Excluding H···H contacts, four short contacts (less than the sum of the van der Waals radii) exist. These are: C4···N3 [2.913 (12) Å], C5···N3 [2.960 (2) Å], C5···N2 [3.000 (14) Å] and C6···N2 [2.928 (10) Å]. Two short contacts are also observed between neighbouring monomers for C1···O2(x, 1/2 - y, 1/2 + z) [2.988 (6) Å] and Ag1···O1(x, 1/2 - y, 1/2 + z) [3.047 (10) Å].

Comparing the average C—C (1.531 Å), Ag—C (2.098 Å), NC (1.135 Å) and N—C (1.455 Å) bond distances and average Ag—C—N (172.0°) and C—Ag—C (159.9°) bond angles of {Ag(I)[CNCH2C(CH3)2CH2NC]NO3}n with their analogous bond distances [average C—C (1.548 Å), Ag—C (2.116 Å), NC (1.160 Å), N—C (1.480 Å)] and angles [average Ag—C—N (164.0°) and C—Ag—C (159.9°)] in {Ag(I)[CNCH2C(CH3)2CH2NC]Cl}n, although the conformations of the bidentate CNCH2C(CH3)2CH2NC ligand in both polymeric strucures are almost alike, it can be concluded that both molecular structures are very similar. Thus, the counteranion (NO3 or Cl) plays no effective role in changing the polymeric structure of the complex.

For related literature, see: Al-Ktaifani, Rukiah & Shaaban (2008); Boultif & Louër (2004); Chemin et al. (1996); Espinet et al. (2000); Favre-Nicolin & Černý (2002); Finger et al. (1994); Fortin et al. (1997, 2000); Harvey (2001); Laugier & Bochu (2001); Mann et al. (1977); Moigno et al. (2002); Perreault et al. (1993); Petříček et al. (2000); Sakata et al. (2003); Sigal et al. (1980).

Computing details top

Data collection: WinXpow (Stoe & Cie, 1999); cell refinement: JANA2000 (Petříček et al., 2000); data reduction: WinXpow (Stoe & Cie, 1999); program(s) used to solve structure: FOX (Favre-Nicolin & Černý, 2002); program(s) used to refine structure: JANA2000 (Petříček et al., 2000); molecular graphics: PLATON (Spek, 2003); software used to prepare material for publication: JANA2000 (Petříček et al., 2000).

Figures top
[Figure 1] Fig. 1. The crystal structure of polymer (I), viewed parallel to the a axis. H atoms have been omitted
[Figure 2] Fig. 2. The asymmetric unit of (I), showing the atom-labelling scheme.
[Figure 3] Fig. 3. Final observed (points), calculated (line) and difference profiles for the Rietveld refinement of (I).
Poly[(µ2-2,2-dimethylpropane-1,3-diyl diisocyanide)-µ2-nitrato-silver(I)] top
Crystal data top
[Ag(NO3)(C7H10N2)]F(000) = 1152
Mr = 292Dx = 1.853 Mg m3
Orthorhombic, PbcaCu Kα1 radiation, λ = 1.54060 Å
Hall symbol: -P 2ac 2abµ = 15.39 mm1
a = 16.8649 (8) ÅT = 295 K
b = 16.5864 (9) ÅParticle morphology: fine powder (visual estimate)
c = 7.4838 (4) Ålight-yellow
V = 2093.43 (19) Å3flat sheet, 7.00 × 7.00 mm
Z = 8Specimen preparation: Prepared at 295 K and 101.3 kPa
Data collection top
Stoe STADI P transmission
diffractometer
Scan method: step
Radiation source: sealed X-ray tubeAbsorption correction: for a cylinder mounted on the φ axis
(JANA2000; Petříček et al., 2000)
Curved Ge 111 monochromatorTmin = 0.370, Tmax = 0.400
Specimen mounting: drifted powder between two Mylar foils2θmin = 8.00°, 2θmax = 88.99°, 2θstep = 0.01°
Data collection mode: transmission
Refinement top
Refinement on InetProfile function: pseudo-Voigt
Rp = 0.02892 parameters
Rwp = 0.03618 restraints
Rexp = 0.029H-atom parameters constrained
RBragg = 0.025Weighting scheme based on measured s.u.'s Mesur
R(F) = 0.025(Δ/σ)max = 0.048
8200 data pointsBackground function: 15 Legendre polynoms
Excluded region(s): nonePreferred orientation correction: none
Crystal data top
[Ag(NO3)(C7H10N2)]V = 2093.43 (19) Å3
Mr = 292Z = 8
Orthorhombic, PbcaCu Kα1 radiation, λ = 1.54060 Å
a = 16.8649 (8) ŵ = 15.39 mm1
b = 16.5864 (9) ÅT = 295 K
c = 7.4838 (4) Åflat sheet, 7.00 × 7.00 mm
Data collection top
Stoe STADI P transmission
diffractometer
Absorption correction: for a cylinder mounted on the φ axis
(JANA2000; Petříček et al., 2000)
Specimen mounting: drifted powder between two Mylar foilsTmin = 0.370, Tmax = 0.400
Data collection mode: transmission2θmin = 8.00°, 2θmax = 88.99°, 2θstep = 0.01°
Scan method: step
Refinement top
Rp = 0.0288200 data points
Rwp = 0.03692 parameters
Rexp = 0.02918 restraints
RBragg = 0.025H-atom parameters constrained
R(F) = 0.025
Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
Ag10.09520 (7)0.18220 (5)0.44903 (12)0.0617 (4)
C10.1759 (5)0.1075 (5)0.5817 (13)0.051 (3)*
C20.2987 (4)0.0472 (6)0.7379 (13)0.064 (3)*
C30.3761 (5)0.0873 (5)0.6642 (11)0.071 (5)*
C40.4442 (5)0.0569 (6)0.7734 (11)0.074 (3)*
C50.3881 (8)0.0751 (4)0.4685 (11)0.074 (3)*
C60.3634 (4)0.1790 (4)0.7096 (12)0.064 (3)*
C70.4880 (4)0.2599 (6)0.6156 (14)0.051 (3)*
N10.2023 (2)0.1719 (4)0.0604 (9)0.066 (5)*
N20.2283 (4)0.0752 (5)0.6449 (10)0.042 (3)*
N30.4337 (4)0.2246 (4)0.6586 (10)0.042 (3)*
O10.1327 (3)0.1588 (4)0.1165 (5)0.086 (5)
O20.2140 (3)0.2239 (3)0.0552 (10)0.083 (4)
O30.2594 (3)0.1347 (4)0.1265 (9)0.071 (4)
H2a0.2935790.0588880.8657730.0769*
H2b0.3026910.011490.7265930.0769*
H4a0.4936650.0710620.7151050.0888*
H4b0.4424940.0813130.8911310.0888*
H4c0.4405670.0011950.7846370.0888*
H5a0.3671110.1210720.4039190.0888*
H5b0.3606170.0265780.4308550.0888*
H5c0.4442620.0696340.4435970.0888*
H6a0.3173590.1993590.6437550.0769*
H6b0.354130.1850280.8381880.0769*
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Ag10.0343 (6)0.0663 (7)0.0844 (8)0.0038 (10)0.0031 (10)0.0031 (9)
O10.041 (7)0.158 (10)0.060 (7)0.004 (7)0.013 (5)0.026 (6)
O30.071 (7)0.067 (7)0.076 (8)0.028 (6)0.014 (6)0.009 (6)
O20.132 (8)0.045 (7)0.073 (8)0.009 (6)0.032 (8)0.004 (7)
Geometric parameters (Å, º) top
Ag1—C12.092 (8)C4—H4b0.973
Ag1—C7i2.104 (8)C4—H4c0.970
Ag1—O12.597 (4)C5—H5a0.972
Ag1—O2ii2.538 (5)C5—H5b0.972
C1—N21.136 (11)C5—H5c0.970
N2—C21.452 (10)C6—N31.457 (10)
C2—C31.566 (11)C6—H6a0.981
C2—H2a0.979C6—H6b0.977
C2—H2b0.979N3—C71.134 (10)
C3—C41.496 (12)N1—O11.265 (6)
C3—C51.487 (11)N1—O31.246 (8)
C3—C61.574 (11)N1—O21.236 (9)
C4—H4a0.969
C1—Ag1—C7i159.9 (3)C5—C3—C6111.4 (6)
C1—Ag1—O1102.1 (2)H4a—C4—H4b109.3
C1—Ag1—O2ii81.7 (3)H4a—C4—H4c109.6
C7i—Ag1—O193.2 (2)H4b—C4—H4c109.3
C7i—Ag1—O2ii113.3 (3)C3—C6—N3109.5 (6)
O1—Ag1—O2ii83.6 (2)C3—C6—H6a109.3
Ag1—C1—N2169.3 (7)C3—C6—H6b109.6
C1—N2—C2170.3 (9)N3—C6—H6a109.4
N2—C2—C3112.1 (7)N3—C6—H6b109.5
N2—C2—H2a109.4H6a—C6—H6b109.5
N2—C2—H2b109.4C6—N3—C7178.7 (8)
H2a—C2—H2b106.7Ag1iii—C7—N3174.6 (7)
C2—C3—C4107.7 (6)O1—N1—O3120.0 (6)
C2—C3—C5113.7 (7)O1—N1—O2120.0 (5)
C2—C3—C6102.7 (6)O3—N1—O2120.0 (5)
C4—C3—C5112.6 (8)Ag1—O1—N1121.2 (4)
C4—C3—C6108.1 (7)Ag1iv—O2—N1107.1 (4)
N2—C2—C3—C4177.8 (7)C2—C3—C6—N3176.5 (6)
N2—C2—C3—C556.5 (10)C4—C3—C6—N362.7 (8)
N2—C2—C3—C663.7 (8)C5—C3—C6—N361.6 (9)
Symmetry codes: (i) x1/2, y+1/2, z+1; (ii) x, y+1/2, z+1/2; (iii) x+1/2, y+1/2, z+1; (iv) x, y+1/2, z1/2.

Experimental details

Crystal data
Chemical formula[Ag(NO3)(C7H10N2)]
Mr292
Crystal system, space groupOrthorhombic, Pbca
Temperature (K)295
a, b, c (Å)16.8649 (8), 16.5864 (9), 7.4838 (4)
V3)2093.43 (19)
Z8
Radiation typeCu Kα1, λ = 1.54060 Å
µ (mm1)15.39
Specimen shape, size (mm)Flat sheet, 7.00 × 7.00
Data collection
DiffractometerStoe STADI P transmission
Specimen mountingDrifted powder between two Mylar foils
Data collection modeTransmission
Scan methodStep
Absorption correctionFor a cylinder mounted on the φ axis
(JANA2000; Petříček et al., 2000)
Tmin, Tmax0.370, 0.400
2θ values (°)2θmin = 8.00 2θmax = 88.99 2θstep = 0.01
Refinement
R factors and goodness of fitRp = 0.028, Rwp = 0.036, Rexp = 0.029, RBragg = 0.025, R(F) = 0.025, χ2 = 1.613
No. of parameters92
No. of restraints18
H-atom treatmentH-atom parameters constrained

Computer programs: WinXpow (Stoe & Cie, 1999), JANA2000 (Petříček et al., 2000), FOX (Favre-Nicolin & Černý, 2002), PLATON (Spek, 2003).

Selected geometric parameters (Å, º) top
Ag1—C12.092 (8)C1—N21.136 (11)
Ag1—C7i2.104 (8)N2—C21.452 (10)
Ag1—O12.597 (4)C6—N31.457 (10)
Ag1—O2ii2.538 (5)N3—C71.134 (10)
C1—Ag1—C7i159.9 (3)O1—Ag1—O2ii83.6 (2)
C1—Ag1—O1102.1 (2)Ag1—C1—N2169.3 (7)
C1—Ag1—O2ii81.7 (3)C1—N2—C2170.3 (9)
C7i—Ag1—O193.2 (2)C6—N3—C7178.7 (8)
C7i—Ag1—O2ii113.3 (3)Ag1iii—C7—N3174.6 (7)
N2—C2—C3—C4177.8 (7)C2—C3—C6—N3176.5 (6)
N2—C2—C3—C556.5 (10)C4—C3—C6—N362.7 (8)
N2—C2—C3—C663.7 (8)C5—C3—C6—N361.6 (9)
Symmetry codes: (i) x1/2, y+1/2, z+1; (ii) x, y+1/2, z+1/2; (iii) x+1/2, y+1/2, z+1.
 

Subscribe to Acta Crystallographica Section C: Structural Chemistry

The full text of this article is available to subscribers to the journal.

If you have already registered and are using a computer listed in your registration details, please email support@iucr.org for assistance.

Buy online

You may purchase this article in PDF and/or HTML formats. For purchasers in the European Community who do not have a VAT number, VAT will be added at the local rate. Payments to the IUCr are handled by WorldPay, who will accept payment by credit card in several currencies. To purchase the article, please complete the form below (fields marked * are required), and then click on `Continue'.
E-mail address* 
Repeat e-mail address* 
(for error checking) 

Format*   PDF (US $40)
   HTML (US $40)
   PDF+HTML (US $50)
In order for VAT to be shown for your country javascript needs to be enabled.

VAT number 
(non-UK EC countries only) 
Country* 
 

Terms and conditions of use
Contact us

Follow Acta Cryst. C
Sign up for e-alerts
Follow Acta Cryst. on Twitter
Follow us on facebook
Sign up for RSS feeds