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Crystal structure of poly[(μ3-thio­cyanato-κ3N:S:S)(tri­methyl­phosphine sulfide-κS)copper(I)]

aDepartment of Chemistry, Fordham University, 441 East Fordham Road, Bronx, NY 10458, USA
*Correspondence e-mail: pcorfield@fordham.edu

Edited by S. Parkin, University of Kentucky, USA (Received 30 August 2014; accepted 26 September 2014; online 4 October 2014)

In the title compound, [Cu(NCS)(C3H9PS)]n, the thio­cyanate ions bind the CuI atoms covalently, forming infinite –Cu—SCN—Cu– chains parallel to the a axis. Each CuI atom is also coordinated to a tri­methyl­phosphine sulfide group via a Cu—S bond. Two crystallographically independent chains propagate in opposite directions, and are held together in a ribbon arrangement by long bonds between CuI atoms in the first chain and thio­cyanate S atoms in the second, with Cu—S = 2.621 (1) Å. The geometry around the CuI atoms in the first chain is distorted tetra­hedral, with angles involving the long Cu—S bond much less than ideal, and the S—Cu—N angle between the phosphine sulfide S atom and the thio­cyanate N atom opening out to 133.19 (9)°. Each CuI atom in the second chain appears to be disordered between two positions 0.524 (4) Å apart, with occupancy factors of 0.647 (6) and 0.353 (6). The CuI atom in the major site is in a distorted trigonal–planar configuration, with the S—Cu—N angle between the phosphine sulfide and the thio­cyanate N atom again opened out, to 137.01 (15)°. The CuI atom in the minor site, however, forms in addition a long bond [Cu—S = 2.702 (5) Å] to the phosphine sulfide of the first chain, not the thio­cyanate S atom, to provide a further link between the chains.

1. Chemical context

The synthesis and metal coordination reactions of phosphine sulfides is of continuing inter­est (Sues et al., 2014[Sues, E. S., Lough, A. J. & Morris, R. H. (2014). Chem. Commun. 50, 4707-4710.]; Tiedemann et al., 2014[Tiedemann, M. A., Mandell, C. L., Chan, B. C. & Nataro, C. (2014). Inorg. Chim. Acta. doi: 10.1016/j. ica. 2014.06.004.]). The title compound was synthesized by Tiethof et al. (1974[Tiethof, J. A., Hetey, A. T. & Meek, D. W. (1974). Inorg. Chem. 13, 2505-2509.]) as part of an early series of studies on the coord­in­ation chemistry of copper(I) with these sulfur ligands, which established the importance of trigonal–planar coordination for copper(I), then still rare. Indeed, the structure of the cation in [Cu(Me3PS)3]ClO4 (Eller & Corfield, 1971[Eller, P. G. & Corfield, P. W. R. (1971). J. Chem. Soc. Chem. Commun. pp. 105-106.]) was the first example of trigonal–planar coordination in a monomeric copper complex.

[Scheme 1]

Use of the pseudohalide thio­cyanate in the synthesis of coordination compounds is a well-used route in the design of polymeric structures. Early papers on copper thio­cyanate polymers involving amine adducts include Raston et al. (1979[Raston, C. L., Walter, B. & White, A. H. (1979). Aust. J. Chem. 32, 2757-2761.]) and Healy et al. (1984[Healy, P. C., Pakawatchai, C., Papasergio, R. I., Patrick, V. A. & White, A. H. (1984). Inorg. Chem. 23, 3769-3776.]). More recent studies include papers on the optical properties of self-assembled amine copper(I) thio­cyanate complexes by Niu et al. (2008[Niu, Y.-Y., Wu, B.-L., Guo, X.-L., Song, Y.-L., Liu, X.-C., Zhang, H.-Y., Hou, H.-W., Niu, C.-Y. & Ng, S.-W. (2008). Cryst. Growth Des. 8, 2393-2401.]) and Miller et al. (2011[Miller, K. M., McCullough, S. M., Lepekhina, E. A., Thibau, I. J., Pike, R. D., Li, X., Killarney, J. P. & Patterson, H. H. (2011). Inorg. Chem. 50, 7239-7249.]), as well as studies on magnetic properties of a number of similar copper(II) complexes by Machura et al. (2013[Machura, B., Świtlicka, A., Mroziński, J., Kalińska, B. & Kruszynski, R. (2013). Polyhedron, 52, 1276-1286.]).

2. Structural commentary

The previously determined structure of [Cu(Me3PS)Cl]3 (Tiethof et al., 1973[Tiethof, J. A., Stalick, J. K. & Meek, D. W. (1973). Inorg. Chem. 12, 1170-1174.]) consists of a six-membered ring of alternating Cu and S atoms, with trigonal–planar coordination for the CuI atoms completed by bonds to a Cl atom. It was noteworthy that the Me3PS phosphine sulfide ligands bridged the CuI atoms to form the ring, and not the chlorine atoms as might have been expected. The structure of [Cu(Me3PS)SCN] was undertaken to determine whether this trimeric structure persisted in the presence of the thio­cyanate ligand.

The present work determined that tri­methyl­phosphine­copper(I) thio­cyanate crystallizes as a one-dimensional polymer, rather than as the discrete trimers found for the chloride analog. Thio­cyanate ions bind to two separate copper(I) atoms through Cu—N and Cu—S bonds. In the crystal, the two CuI atoms are related by translation, which leads to the formation of infinite —Cu—SCN—Cu— chains parallel to the a axis. Although the Cu—N—C angles are approximately linear, the Cu—S—C angles are bent considerably, as expected (see Table 1[link]). Each CuI atom is also coordinated to a terminal Me3PS group via a Cu—S bond.

Table 1
Selected geometric parameters (Å, °)

Cu1—N3 1.943 (3) Cu2B—N4i 1.969 (6)
Cu1—S1 2.2830 (11) Cu2B—S2 2.315 (5)
Cu1—S3 2.3431 (11) Cu2B—S4 2.416 (5)
Cu2A—N4i 1.894 (4) S1—P1 1.9935 (13)
Cu2A—S2 2.206 (3) S2—P2 1.9848 (14)
Cu2A—S4 2.316 (3)    
       
P1—S1—Cu1 105.99 (5) C4—S4—Cu2A 102.18 (13)
P2—S2—Cu2A 106.09 (8) C3—N3—Cu1 164.6 (3)
P2—S2—Cu2B 106.55 (13) C4—N4—Cu2Aii 169.9 (3)
C3i—S3—Cu1 102.90 (12) C4—N4—Cu2Bii 166.1 (3)
C4—S4—Cu2B 100.44 (16)    
Symmetry codes: (i) x-1, y, z; (ii) x+1, y, z.

Two crystallographically independent chains propagate in opposite directions, and are held together in a ribbon arrangement by long Cu—S bonds between the chains. While no disorder was seen in the first chain, each CuI atom in the second chain appears to be disordered over two positions, Cu2A and Cu2B, 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%, and slightly different coordination spheres (Fig. 3).

CuI atoms in the first chain bind to thio­cyanate sulfur atoms in the second, with Cu1—S4 = 2.621 (1) Å. Also, one of the disordered CuI atoms in the second chain forms a long bond to the phosphine sulfide of the first chain, with Cu2B—S1 = 2.702 (5) Å, forming another link between the chains (Figs. 1[link] and 2[link]), and a ladder arrangement that is seen also in one of the structures in Healy et al. (1984[Healy, P. C., Pakawatchai, C., Papasergio, R. I., Patrick, V. A. & White, A. H. (1984). Inorg. Chem. 23, 3769-3776.]) and in Niu et al. (2008[Niu, Y.-Y., Wu, B.-L., Guo, X.-L., Song, Y.-L., Liu, X.-C., Zhang, H.-Y., Hou, H.-W., Niu, C.-Y. & Ng, S.-W. (2008). Cryst. Growth Des. 8, 2393-2401.]). The Cu—Cu distances across the chain are 3.656 (3) Å for Cu1—Cu2A and 3.351 (5) Å for Cu2B.[link]

[Figure 1]
Figure 1
The ribbon structure of the title polymer, with displacement ellipsoids drawn at the 50% level, showing Cu2 in position A. Hydrogen atoms are omitted.
[Figure 2]
Figure 2
The alternate ribbon structure of the title polymer, showing the environment of Cu2 in position B, with ellipsoids at the 50% level. Hydrogen atoms omitted.
[Figure 3]
Figure 3
The Cu2 ellipsoids after and before the disordered model was introduced. Displacement ellipsoids are drawn at the 50% level.

In the current structure, the two independent Me3PS groups are non-equivalent: the group in the second chain, C21–C23, P2 and S2, is terminal, while that in the first chain, C11–C13, P1 and S1, forms an asymmetric bridge between Cu1 and the minor component atom Cu2B. This may explain the observation of two different P=S stretching bands in the infra-red spectrum, see below. The two thio­cyanate groups are also non-equivalent, with both S3 and S4 bonded to Cu and N atoms, but S4 forming an additional long bond to Cu1. The non-equivalent groups do not show significant differences in geometry, however (Table 1[link]).

The geometry around Cu1 atoms, in the first chain, is distorted tetra­hedral, with angles involving the long Cu1—S4 bond much less than ideal, and the S1—Cu1—N3 angle between the phosphine sulfide and the thio­cyanate N atom increased to 133.19 (9)°. The geometry around the disordered CuI atom in the major site, Cu2A, is in a distorted trigonal–planar configuration, with the S2—Cu2A—N4 angle between the phosphine S and the thio­cyanate N atoms again opened out, to 137.01 (15)°. Atom Cu2B has an irregular tetra­hedral configuration. The geometry at the three-coordinated sulfur atoms S1 and S4 is trigonal–pyramidal rather than trigonal–planar, with the sum of the angles at S1 = 303.2°, while at S4 the sum is 294.8° for angles involving Cu2A and 281.0° for angles with Cu2B.

3. Supra­molecular features

A packing diagram viewed down the a* axis is shown in Fig. 4[link]. There are no strong inter­actions between the chains, and all inter­molecular contacts appear normal. The shortest inter­molecular contacts are H13A⋯H23B(1 + x, y, z), at 2.53 Å, and H12A⋯H12A(1 − x, 1 − y, 1 − z) at 2.57 Å. All other H⋯H contacts are greater than 2.7 Å.

[Figure 4]
Figure 4
Packing of the title complex, viewed along the a* axis, with ellipsoid outlines at 30% probability.

4. Database survey

Entry CMPSCU in the Cambridge Structure Database (CSD) is taken from the abstract of our presentation at the 1973 Winter Meeting of the American Crystallographic Association. No coordinates were given.

A search of the database with the fragment Cu—S—C≡N—Cu fingered 100 analyzable structures with 164 thio­cyanate groups. The average thio­cyanate geometries were: C≡N = 1.152 (17), S—C = 1.65 (2)Å; S—C≡N = 178.2 (14)°. Corresponding parameters in the present structure are indistinguishable from these average values. A much greater spread is seen in average parameters involving Cu, reflecting the diversity of chemical inter­actions in these structures. For example, average values for Cu—S distances are 2.5 (2) Å, with a range from 2.20 to 3.12 Å.

5. Synthesis and crystallization

Details of the synthesis and characterization of the title compound are given in Tiethof et al. (1974[Tiethof, J. A., Hetey, A. T. & Meek, D. W. (1974). Inorg. Chem. 13, 2505-2509.]), which describes the preparation and characterization of a series of copper(I) complexes with tertiary phosphine sulfide, phosphine selenide, and arsine sulfide ligands. Solid LiSCN (0.59 mmol) was stirred with 7 mL of a solution of 0.63 mmol of [Cu(Me3PS)3]BF4 in aceto­nitrile for 30 min. The resultant solid was collected, washed with ether, dried in vacuo, and characterized by C, H, and N elemental analysis. The infra-red spectrum of a solid sample in a Nujol mull gave bands attributed to P=S stretching at 543 and 546 cm−1. These frequencies are similar to the frequency of 540 cm−1 observed for [Cu(Me3PS)3]BF4, where the phosphine ligands are terminally bonded to copper as in the present structure, and significantly different from the P=S frequency of 564 cm−1 observed for the free ligand, Me3PS.

6. Refinement details

Initial refinements with anisotropic displacement parameters for all non-hydrogen atoms and constrained hydrogen atom parameters converged smoothly to R = 0.0315 for F2>2σ, but a difference Fourier synthesis at this stage showed unacceptable features, with a hole of −1.0 e/A3 and two peaks of 0.7 e/A3 near Cu2, while there were no significant peaks or holes near Cu1. In addition, the temperature factors for Cu2 indicated an ellipsoid much elongated compared to that for Cu1 (Fig. 3[link]). In case these features were related to systematic anisotropies that might have existed in the data collection, a trial was made to apply a smoothly varying scale factor by a 12 parameter model with XABS2 (Parkin et al., 1995[Parkin, S., Moezzi, B. & Hope, H. (1995). J. Appl. Cryst. 28, 53-56.]). This had no significant effect on either the difference Fourier map or the R values, and the trial was abandoned. Instead, a model with Cu2 disordered equally between two positions was refined, which converged at R = 0.0307 for F2>2σ, and showed maximum and minimum residual electron densities at 0.71 and −0.81 e/A3 near Cu2B and Cu2A, respectively, indicating that the sites were not equally occupied. Allowing the occupancy factors to vary led to the final model, with R = 0.0265 for F2>2σ, and residual electron density maxima of 0.29 and −0.31 e/A3 near S and P atoms. The disordered CuII atoms sites are 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%. To facilitate convergence, the Uij for the disordered Cu atoms were constrained to be identical. It is likely that S2 could also be disordered, reflecting bonding to the two different Cu2 sites. We have not pursued attempts to model this.

The two partial copper positions might have represented alternating sites in a larger unit cell with the short a axis doubled. This would have made the disorder an artifact due to the data collection in that only reflections with h = 2n would have been collected. However, inspection of precession photographs of the h0l, h1l and h2l layers did not reveal any indication of doubling of the a axis. Furthermore, if that had been the case, the occupancies of the disorder components would have refined to approximately 0.5 rather than 0.647 (6) and 0.353 (6).

H atoms were constrained to idealized positions with C—H distances of 0.96 Å. The orientations of the methyl groups were determined by calculation of electron density in the toroid that should contain the H atoms of the idealized methyl groups. The Ueq values for the H atoms were fixed at 1.2 times the Uiso of their bonded C atoms.

Values for the Goodness of Fit (GOOF) near the end of the refinements were rather low, at 0.66, implying that at least some of the estimated σ values for the data were too high. The factor p in the data processing (Corfield et al., 1973[Corfield, P. W. R., Dabrowiak, J. C. & Gore, E. S. (1973). Inorg. Chem. 12, 1734-1740.]) had originally been set at 0.06, a value that now seemed too large for such a highly refined structure. The σ values were adjusted to correspond to p = 0.05 with the equation: [σ(new)/F2]2 = [σ(old)/F2]2−(0.062−0.052). In addition, σ values for 182 very weak reflections, which had been grossly overestimated previously, were set equal to the average value found for the 145 reflections observed with I<0. (These reflections were set to F2 = 0.) Final refinements with these adjustments to the σ values raised the value of the GOOF to 0.79 with no significant changes to any parameters.

Crystal data, data collection and structure refinement details are summarized in Table 2[link].

Table 2
Experimental details

Crystal data
Chemical formula [Cu(NCS)(C3H9PS)]
Mr 229.75
Crystal system, space group Monoclinic, P21/c
Temperature (K) 298
a, b, c (Å) 5.793 (3), 14.091 (3), 22.064 (7)
β (°) 98.945 (17)
V3) 1779.2 (11)
Z 8
Radiation type Cu Kα
μ (mm−1) 8.73
Crystal size (mm) 0.31 × 0.06 × 0.05
 
Data collection
Diffractometer Picker 4-circle
Absorption correction Gaussian (Busing & Levy, 1957[Busing, W. R. & Levy, H. A. (1957). Acta Cryst. 10, 180-182.])
Tmin, Tmax 0.433, 0.704
No. of measured, independent and observed [I > 2σ(I)] reflections 6315, 2912, 2144
Rint 0.058
(sin θ/λ)max−1) 0.579
 
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.027, 0.076, 0.79
No. of reflections 2912
No. of parameters 174
H-atom treatment H-atom parameters constrained
Δρmax, Δρmin (e Å−3) 0.29, −0.31
Computer programs: Corfield (1972[Corfield, P. W. R. (1972). Local versions of standard programs, written at Ohio State University.]), SHELXL97 (Sheldrick, 2008[Sheldrick, G. M. (2008). Acta Cryst. A64, 112-122.]) and ORTEPIII (Burnett & Johnson, 1996[Burnett, M. N. & Johnson, C. K. (1996). ORTEPIII. Report ORNL-6895. Oak Ridge National Laboratory, Tennessee, USA.]). Data reduction followed procedures in Corfield et al. (1973[Corfield, P. W. R., Dabrowiak, J. C. & Gore, E. S. (1973). Inorg. Chem. 12, 1734-1740.]) with p = 0.06, with programs written by Corfield and by Graeme Gainsford, local superposition program (Corfield, 1972[Corfield, P. W. R. (1972). Local versions of standard programs, written at Ohio State University.]).

Supporting information


Chemical context top

The synthesis and metal coordination reactions of phosphine sulfides is of continuing inter­est (Sues et al., 2014); Tiedemann et al., 2014). The title compound was synthesized by Tiethof et al. (1974) as part of an early series of studies on the coordination chemistry of copper(I) with these sulfur ligands, which established the importance of trigonal–planar coordination for copper(I), then still rare. Indeed, the structure of the cation in [Cu(Me3PS)3]ClO4 (Eller & Corfield, 1971) was the first example of trigonal–planar coordination in a monomeric copper complex.

Use of the pseudohalide thio­cyanate in the synthesis of coordination compounds is a well-used route in the design of polymeric structures. Early papers on copper thio­cyanate polymers involving amine adducts include Raston et al. (1979) and Healy et al. (1984). More recent studies include papers on the optical properties of self-assembled amine copper(I) thio­cyanate complexes by Niu et al. (2008) and Miller et al. (2011), as well as studies on magnetic properties of a number of similar copper(II) complexes by Machura et al. (2013).

Structural commentary top

The previously determined structure of [Cu(Me3PS)Cl]3 (Tiethof et al., 1973) consists of a six-membered ring of alternating Cu and S atoms, with trigonal–planar coordination for the CuI atoms completed by bonds to a Cl atom. It was noteworthy that the Me3PS phosphine sulfide ligands bridged the CuI atoms to form the ring, and not the chlorine atoms as might have been expected. The structure of [Cu(Me3PS)SCN] was undertaken to determine whether this trimeric structure persisted in the presence of the thio­cyanate ligand.

The present work determined that tri­methyl­phosphinecopper(I) thio­cyanate crystallizes as a one-dimensional polymer, rather than as the discrete trimers found for the chloride analog. Thio­cyanate ions bind to two separate copper atoms through Cu—N and Cu—S bonds. In the crystal, the two CuI atoms are related by translation, which leads to the formation of infinite —Cu—SCN—Cu— chains parallel to the a axis. Although the Cu—N—C angles are approximately linear, the Cu—S—C angles are bent considerably, as expected (see Table 1). Each CuI atom is also coordinated to a terminal Me3PS group via a Cu—S bond.

Two crystallographically independent chains propagate in opposite directions, and are held together in a ribbon arrangement by long Cu—S bonds between the chains. While no disorder was seen in the first chain, each CuI atom in the second chain appears to be disordered over two positions, Cu2A and Cu2B, 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%, and slightly different coordination spheres (Fig. 3).

CuI atoms in the first chain bind to thio­cyanate sulfur atoms in the second, with Cu1—S4 = 2.621 (1) Å. Also, one of the disordered CuI atoms in the second chain forms a long bond to the phosphine sulfide of the first chain, with Cu2B—S1 = 2.702 (5) Å, forming another link between the chains (Figs. 1 and 2), and a ladder arrangement that is seen also in one of the structures in Healy et al. (1984) and in Niu et al. (2008). The Cu—Cu distances across the chain are 3.656 (3) Å for Cu1—Cu2A and 3.351 (5) Å for Cu2B.

In the current structure, the two independent Me3PS groups are non-equivalent: the group in the second chain, C21–C23, P2 and S2, is terminal, while that in the first chain, C11–C13, P1 and S1, forms an asymmetric bridge between Cu1 and the minor component atom Cu2B. This may explain the observation of two different PS stretching bands in the infra-red spectrum, see below. The two thio­cyanate groups are also non-equivalent, with both S3 and S4 bonded to Cu and N atoms, but S4 forming an additional long bond to Cu1. The non-equivalent groups do not show significant differences in geometry, however (Table 1).

The geometry around Cu1 atoms, in the first chain, is distorted tetra­hedral, with angles involving the long Cu1—S4 bond much less than ideal, and the S1—Cu1—N3 angle between the phosphine sulfide and the thio­cyanate N atom increased to 133.19 (9)°. The geometry around the disordered CuI atom in the major site, Cu2A, is in a distorted trigonal–planar configuration, with the S2—Cu2A—N4 angle between the phosphine S and the thio­cyanate N atoms again opened out, to 137.01 (15)°. Atom Cu2B has an irregular tetra­hedral configuration. The geometry at the three-coordinated sulfur atoms S1 and S4 is trigonal–pyramidal rather than trigonal–planar, with the sum of the angles at S1 = 303.2°, while at S4 the sum is 294.8° for angles involving Cu2A and 281.0° for angles with Cu2B.

Supra­molecular features top

A packing diagram viewed down the a* axis is shown in Fig. 4. There are no strong inter­actions between the chains, and all inter­molecular contacts appear normal. The shortest inter­molecular contacts are H13A···H23B(1+x, y, z), at 2.53 Å, and H12A···H12A(1-x, 1-y, 1-z) at 2.57 Å. All other H···H contacts are greater than 2.7 Å.

Database survey top

Entry CMPSCU in the Cambridge Structure Database (CSD) is taken from the abstract of our presentation at the 1973 Winter Meeting of the American Crystallographic Association. No coordinates were given.

A search of the database with the fragment Cu—S—CN—Cu fingered 100 analyzable structures with 164 thio­cyanate groups. The average thio­cyanate geometries were: CN = 1.152 (17), S—C = 1.65 (2)Å; S—CN = 178.2 (14)°. Corresponding parameters in the present structure are indistinguishable from these average values. A much greater spread is seen in average parameters involving Cu, reflecting the diversity of chemical inter­actions in these structures. For example, average values for Cu—S distances are 2.5 (2)Å, with a range from 2.20 to 3.12 Å.

Synthesis and crystallization top

Details of the synthesis and characterization of the title compound are given in Tiethof et al. (1974), which describes the preparation and characterization of a series of copper(I) complexes with tertiary phosphine sulfide, phosphine selenide, and arsine sulfide ligands. Solid LiSCN (0.59 mmol) was stirred with 7 mL of a solution of 0.63 mmol of [Cu(Me3PS)3]BF4 in aceto­nitrile for 30 min. The resultant solid was collected, washed with ether, dried in vacuo, and characterized by C, H, and N elemental analysis. The infra-red spectrum of a solid sample in a Nujol mull gave bands attributed to PS stretching at 543 and 546 cm-1. These frequencies are similar to the frequency of 540 cm-1 observed for [Cu(Me3PS)3]BF4, where the phosphine ligands are terminally bonded to copper as in the present structure, and significantly different from the PS frequency of 564 cm-1 observed for the free ligand, Me3PS.

Refinement details top

Initial refinements with anisotropic temperature factors for all non-hydrogen atoms and constrained hydrogen atom parameters converged smoothly to R = 0.0315 for F2>2σ, but a difference Fourier synthesis at this stage showed unacceptable features, with a hole of -1.0 e/A3 and two peaks of 0.7 e/A3 near Cu2, while there were no significant peaks or holes near Cu1. In addition, the thermal parameters for Cu2 indicated an ellipsoid much elongated compared to that for Cu1 (Fig. 3). In case these features were related to systematic anisotropies that might have existed in the data collection, a trial was made to apply a smoothly varying scale factor by a 12 parameter model with XABS2 (Parkin et al., 1995). This had no significant effect on either the difference Fourier map or the R-values, and the trial was abandoned. Instead, a model with Cu2 disordered equally between two positions was refined, which converged at R = 0.0307 for F2>2σ, and showed maximum and minimum residual electron densities at 0.71 and -0.81 e/A3 near Cu2B and Cu2A, respectively, indicating that the sites were not equally occupied. Allowing the occupancy factors to vary led to the final model, with R = 0.0265 for F2>2σ, and residual electron density maxima of 0.29 and -0.31 e/A3 near S and P atoms. The disordered CuI atoms sites are 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%. To facilitate convergence, the Uij for the disordered Cu atoms were constrained to be identical.

It is likely that S2 could also be disordered, reflecting bonding to the two different Cu2 sites. We have not pursued attempts to model this.

The two partial copper positions might have represented alternating sites in a larger unit cell with the short a axis doubled. This would have made the disorder an artifact due to the data collection in that only reflections with h = 2n would have been collected. However, inspection of precession photographs of the h0l, h1l and h2l layers did not reveal any indication of doubling of the a axis. Furthermore, if that had been the case, the occupancies of the disorder components would have refined to approximately 0.5 rather than 0.647 (6) and 0.353 (6).

H atoms were constrained to idealized positions with C—H distances of 0.96 Å. The orientations of the methyl groups were determined by calculation of electron density in the torid that should contain the H atoms of the idealized methyl groups. The Ueq values for the H atoms were fixed at 1.2 times the Uiso of their bonded C atoms.

Values for the Goodness of Fit (GOOF) near the end of the refinements were rather low, at 0.66, implying that at least some of the estimated σ values for the data were too high. The factor p in the data processing (Corfield et al., 1973) had originally been set at 0.06, a value that now seemed too large for such a highly refined structure. The σ values were adjusted to correspond to p = 0.05 with the equation: [σ(new)/F2]2 = [σ(old)/F2]2 - (0.062-0.052). In addition, σ values for 182 very weak reflections, which had been grossly overestimated previously, were set equal to the average value found for the 145 reflections observed with I<0. (These reflections were set to F2 = 0.) Final refinements with these adjustments to the σ values raised the value of the GOOF to 0.79 with no significant changes to any parameters.

Crystal data, data collection and structure refinement details are summarized in Table 2.

Related literature top

For related literature, see: Corfield et al. (1973); Eller & Corfield (1971); Healy et al. (1984); Machura et al. (2013); Miller et al. (2011); Niu et al. (2008); Parkin et al. (1995); Raston et al. (1979); Sues et al. (2014); Tiedemann et al. (2014); Tiethof et al. (1973, 1974).

Structure description top

The synthesis and metal coordination reactions of phosphine sulfides is of continuing inter­est (Sues et al., 2014); Tiedemann et al., 2014). The title compound was synthesized by Tiethof et al. (1974) as part of an early series of studies on the coordination chemistry of copper(I) with these sulfur ligands, which established the importance of trigonal–planar coordination for copper(I), then still rare. Indeed, the structure of the cation in [Cu(Me3PS)3]ClO4 (Eller & Corfield, 1971) was the first example of trigonal–planar coordination in a monomeric copper complex.

Use of the pseudohalide thio­cyanate in the synthesis of coordination compounds is a well-used route in the design of polymeric structures. Early papers on copper thio­cyanate polymers involving amine adducts include Raston et al. (1979) and Healy et al. (1984). More recent studies include papers on the optical properties of self-assembled amine copper(I) thio­cyanate complexes by Niu et al. (2008) and Miller et al. (2011), as well as studies on magnetic properties of a number of similar copper(II) complexes by Machura et al. (2013).

The previously determined structure of [Cu(Me3PS)Cl]3 (Tiethof et al., 1973) consists of a six-membered ring of alternating Cu and S atoms, with trigonal–planar coordination for the CuI atoms completed by bonds to a Cl atom. It was noteworthy that the Me3PS phosphine sulfide ligands bridged the CuI atoms to form the ring, and not the chlorine atoms as might have been expected. The structure of [Cu(Me3PS)SCN] was undertaken to determine whether this trimeric structure persisted in the presence of the thio­cyanate ligand.

The present work determined that tri­methyl­phosphinecopper(I) thio­cyanate crystallizes as a one-dimensional polymer, rather than as the discrete trimers found for the chloride analog. Thio­cyanate ions bind to two separate copper atoms through Cu—N and Cu—S bonds. In the crystal, the two CuI atoms are related by translation, which leads to the formation of infinite —Cu—SCN—Cu— chains parallel to the a axis. Although the Cu—N—C angles are approximately linear, the Cu—S—C angles are bent considerably, as expected (see Table 1). Each CuI atom is also coordinated to a terminal Me3PS group via a Cu—S bond.

Two crystallographically independent chains propagate in opposite directions, and are held together in a ribbon arrangement by long Cu—S bonds between the chains. While no disorder was seen in the first chain, each CuI atom in the second chain appears to be disordered over two positions, Cu2A and Cu2B, 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%, and slightly different coordination spheres (Fig. 3).

CuI atoms in the first chain bind to thio­cyanate sulfur atoms in the second, with Cu1—S4 = 2.621 (1) Å. Also, one of the disordered CuI atoms in the second chain forms a long bond to the phosphine sulfide of the first chain, with Cu2B—S1 = 2.702 (5) Å, forming another link between the chains (Figs. 1 and 2), and a ladder arrangement that is seen also in one of the structures in Healy et al. (1984) and in Niu et al. (2008). The Cu—Cu distances across the chain are 3.656 (3) Å for Cu1—Cu2A and 3.351 (5) Å for Cu2B.

In the current structure, the two independent Me3PS groups are non-equivalent: the group in the second chain, C21–C23, P2 and S2, is terminal, while that in the first chain, C11–C13, P1 and S1, forms an asymmetric bridge between Cu1 and the minor component atom Cu2B. This may explain the observation of two different PS stretching bands in the infra-red spectrum, see below. The two thio­cyanate groups are also non-equivalent, with both S3 and S4 bonded to Cu and N atoms, but S4 forming an additional long bond to Cu1. The non-equivalent groups do not show significant differences in geometry, however (Table 1).

The geometry around Cu1 atoms, in the first chain, is distorted tetra­hedral, with angles involving the long Cu1—S4 bond much less than ideal, and the S1—Cu1—N3 angle between the phosphine sulfide and the thio­cyanate N atom increased to 133.19 (9)°. The geometry around the disordered CuI atom in the major site, Cu2A, is in a distorted trigonal–planar configuration, with the S2—Cu2A—N4 angle between the phosphine S and the thio­cyanate N atoms again opened out, to 137.01 (15)°. Atom Cu2B has an irregular tetra­hedral configuration. The geometry at the three-coordinated sulfur atoms S1 and S4 is trigonal–pyramidal rather than trigonal–planar, with the sum of the angles at S1 = 303.2°, while at S4 the sum is 294.8° for angles involving Cu2A and 281.0° for angles with Cu2B.

A packing diagram viewed down the a* axis is shown in Fig. 4. There are no strong inter­actions between the chains, and all inter­molecular contacts appear normal. The shortest inter­molecular contacts are H13A···H23B(1+x, y, z), at 2.53 Å, and H12A···H12A(1-x, 1-y, 1-z) at 2.57 Å. All other H···H contacts are greater than 2.7 Å.

Entry CMPSCU in the Cambridge Structure Database (CSD) is taken from the abstract of our presentation at the 1973 Winter Meeting of the American Crystallographic Association. No coordinates were given.

A search of the database with the fragment Cu—S—CN—Cu fingered 100 analyzable structures with 164 thio­cyanate groups. The average thio­cyanate geometries were: CN = 1.152 (17), S—C = 1.65 (2)Å; S—CN = 178.2 (14)°. Corresponding parameters in the present structure are indistinguishable from these average values. A much greater spread is seen in average parameters involving Cu, reflecting the diversity of chemical inter­actions in these structures. For example, average values for Cu—S distances are 2.5 (2)Å, with a range from 2.20 to 3.12 Å.

For related literature, see: Corfield et al. (1973); Eller & Corfield (1971); Healy et al. (1984); Machura et al. (2013); Miller et al. (2011); Niu et al. (2008); Parkin et al. (1995); Raston et al. (1979); Sues et al. (2014); Tiedemann et al. (2014); Tiethof et al. (1973, 1974).

Synthesis and crystallization top

Details of the synthesis and characterization of the title compound are given in Tiethof et al. (1974), which describes the preparation and characterization of a series of copper(I) complexes with tertiary phosphine sulfide, phosphine selenide, and arsine sulfide ligands. Solid LiSCN (0.59 mmol) was stirred with 7 mL of a solution of 0.63 mmol of [Cu(Me3PS)3]BF4 in aceto­nitrile for 30 min. The resultant solid was collected, washed with ether, dried in vacuo, and characterized by C, H, and N elemental analysis. The infra-red spectrum of a solid sample in a Nujol mull gave bands attributed to PS stretching at 543 and 546 cm-1. These frequencies are similar to the frequency of 540 cm-1 observed for [Cu(Me3PS)3]BF4, where the phosphine ligands are terminally bonded to copper as in the present structure, and significantly different from the PS frequency of 564 cm-1 observed for the free ligand, Me3PS.

Refinement details top

Initial refinements with anisotropic temperature factors for all non-hydrogen atoms and constrained hydrogen atom parameters converged smoothly to R = 0.0315 for F2>2σ, but a difference Fourier synthesis at this stage showed unacceptable features, with a hole of -1.0 e/A3 and two peaks of 0.7 e/A3 near Cu2, while there were no significant peaks or holes near Cu1. In addition, the thermal parameters for Cu2 indicated an ellipsoid much elongated compared to that for Cu1 (Fig. 3). In case these features were related to systematic anisotropies that might have existed in the data collection, a trial was made to apply a smoothly varying scale factor by a 12 parameter model with XABS2 (Parkin et al., 1995). This had no significant effect on either the difference Fourier map or the R-values, and the trial was abandoned. Instead, a model with Cu2 disordered equally between two positions was refined, which converged at R = 0.0307 for F2>2σ, and showed maximum and minimum residual electron densities at 0.71 and -0.81 e/A3 near Cu2B and Cu2A, respectively, indicating that the sites were not equally occupied. Allowing the occupancy factors to vary led to the final model, with R = 0.0265 for F2>2σ, and residual electron density maxima of 0.29 and -0.31 e/A3 near S and P atoms. The disordered CuI atoms sites are 0.524 (4) Å apart, with occupancy factors of 64.7 (6)% and 35.3 (6)%. To facilitate convergence, the Uij for the disordered Cu atoms were constrained to be identical.

It is likely that S2 could also be disordered, reflecting bonding to the two different Cu2 sites. We have not pursued attempts to model this.

The two partial copper positions might have represented alternating sites in a larger unit cell with the short a axis doubled. This would have made the disorder an artifact due to the data collection in that only reflections with h = 2n would have been collected. However, inspection of precession photographs of the h0l, h1l and h2l layers did not reveal any indication of doubling of the a axis. Furthermore, if that had been the case, the occupancies of the disorder components would have refined to approximately 0.5 rather than 0.647 (6) and 0.353 (6).

H atoms were constrained to idealized positions with C—H distances of 0.96 Å. The orientations of the methyl groups were determined by calculation of electron density in the torid that should contain the H atoms of the idealized methyl groups. The Ueq values for the H atoms were fixed at 1.2 times the Uiso of their bonded C atoms.

Values for the Goodness of Fit (GOOF) near the end of the refinements were rather low, at 0.66, implying that at least some of the estimated σ values for the data were too high. The factor p in the data processing (Corfield et al., 1973) had originally been set at 0.06, a value that now seemed too large for such a highly refined structure. The σ values were adjusted to correspond to p = 0.05 with the equation: [σ(new)/F2]2 = [σ(old)/F2]2 - (0.062-0.052). In addition, σ values for 182 very weak reflections, which had been grossly overestimated previously, were set equal to the average value found for the 145 reflections observed with I<0. (These reflections were set to F2 = 0.) Final refinements with these adjustments to the σ values raised the value of the GOOF to 0.79 with no significant changes to any parameters.

Crystal data, data collection and structure refinement details are summarized in Table 2.

Computing details top

Data collection: Corfield (1972); cell refinement: Corfield (1972); data reduction: Data reduction followed procedures in Corfield et al. (1973) with p = 0.06, with programs written by Corfield and by Graeme Gainsford; program(s) used to solve structure: local superposition program (Corfield, 1972); program(s) used to refine structure: SHELXL97 (Sheldrick, 2008); molecular graphics: ORTEPIII (Burnett & Johnson, 1996); software used to prepare material for publication: SHELXL97 (Sheldrick, 2008).

Figures top
[Figure 1] Fig. 1. The ribbon structure of the title molecule, with displacement ellipsoids drawn at the 50% level, showing Cu2 in position A. Hydrogen atoms are omitted.
[Figure 2] Fig. 2. The alternate ribbon structure of the title molecule, showing the environment of Cu2 in position B, with ellipsoids at the 50% level. Hydrogen atoms omitted.
[Figure 3] Fig. 3. The Cu2 ellipsoids before and after the disordered model was introduced. Displacement ellipsoids are drawn at the 50% level.
[Figure 4] Fig. 4. Packing of the title complex, viewed along the a* axis, with ellipsoid outlines at 30% probability.
Poly[(µ3-thiocyanato-κ3N:S:S)(trimethylphosphine sulfide-κS)copper(I)] top
Crystal data top
[Cu(NCS)(C3H9PS)]F(000) = 928
Mr = 229.75Dx = 1.715 Mg m3
Dm = 1.709 Mg m3
Dm measured by flotation
Monoclinic, P21/cCu Kα radiation, λ = 1.5418 Å
Hall symbol: -P 2ybcCell parameters from 19 reflections
a = 5.793 (3) Åθ = 6.4–41.0°
b = 14.091 (3) ŵ = 8.73 mm1
c = 22.064 (7) ÅT = 298 K
β = 98.945 (17)°Rod, colorless
V = 1779.2 (11) Å30.31 × 0.06 × 0.05 mm
Z = 8
Data collection top
Picker 4-circle
diffractometer
2144 reflections with I > 2σ(I)
Radiation source: sealed X-ray tubeRint = 0.058
Oriented graphite 200 reflection monochromatorθmax = 63.3°, θmin = 3.7°
θ/2θ scansh = 06
Absorption correction: gaussian
(Busing & Levy, 1957)
k = 1616
Tmin = 0.433, Tmax = 0.704l = 2525
6315 measured reflections6 standard reflections every 400 reflections
2912 independent reflections intensity decay: 0.6(4)
Refinement top
Refinement on F2Secondary atom site location: difference Fourier map
Least-squares matrix: fullHydrogen site location: inferred from neighbouring sites
R[F2 > 2σ(F2)] = 0.027H-atom parameters constrained
wR(F2) = 0.076 w = 1/[σ2(Fo2)]
S = 0.79(Δ/σ)max = 0.001
2912 reflectionsΔρmax = 0.29 e Å3
174 parametersΔρmin = 0.31 e Å3
0 restraintsExtinction correction: SHELXL97 (Sheldrick, 2008), Fc*=kFc[1+0.001xFc2λ3/sin(2θ)]-1/4
Primary atom site location: structure-invariant direct methodsExtinction coefficient: 0.00128 (9)
Crystal data top
[Cu(NCS)(C3H9PS)]V = 1779.2 (11) Å3
Mr = 229.75Z = 8
Monoclinic, P21/cCu Kα radiation
a = 5.793 (3) ŵ = 8.73 mm1
b = 14.091 (3) ÅT = 298 K
c = 22.064 (7) Å0.31 × 0.06 × 0.05 mm
β = 98.945 (17)°
Data collection top
Picker 4-circle
diffractometer
2144 reflections with I > 2σ(I)
Absorption correction: gaussian
(Busing & Levy, 1957)
Rint = 0.058
Tmin = 0.433, Tmax = 0.7046 standard reflections every 400 reflections
6315 measured reflections intensity decay: 0.6(4)
2912 independent reflections
Refinement top
R[F2 > 2σ(F2)] = 0.0270 restraints
wR(F2) = 0.076H-atom parameters constrained
S = 0.79Δρmax = 0.29 e Å3
2912 reflectionsΔρmin = 0.31 e Å3
174 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
xyzUiso*/UeqOcc. (<1)
Cu10.03939 (9)0.30233 (4)0.41293 (3)0.04640 (17)
Cu2A0.2710 (4)0.3110 (2)0.25554 (15)0.0484 (5)0.647 (6)
Cu2B0.2599 (8)0.3379 (3)0.2721 (2)0.0484 (5)0.353 (6)
S10.17677 (15)0.43301 (6)0.37964 (4)0.0432 (2)
S20.11907 (16)0.39160 (7)0.18567 (4)0.0524 (3)
P10.05098 (15)0.53894 (6)0.37911 (4)0.0356 (2)
P20.38568 (14)0.45343 (6)0.13294 (4)0.0326 (2)
S30.18043 (14)0.20640 (6)0.46933 (4)0.0440 (2)
S40.01342 (14)0.21297 (6)0.30788 (4)0.0372 (2)
N30.3696 (5)0.2829 (2)0.44265 (13)0.0448 (7)
C30.5556 (5)0.2523 (2)0.45340 (14)0.0326 (7)
N40.4265 (5)0.2852 (2)0.27391 (14)0.0488 (8)
C40.2553 (5)0.2565 (2)0.28759 (14)0.0341 (7)
C110.1011 (7)0.6494 (3)0.3727 (2)0.0656 (12)
H11A0.00790.70010.37050.098*
H11B0.17730.65820.40800.098*
H11C0.21570.64920.33630.098*
C120.2638 (7)0.5438 (3)0.44721 (16)0.0566 (11)
H12A0.34720.48470.45230.085*
H12B0.18680.55470.48210.085*
H12C0.37160.59450.44380.085*
C130.2128 (7)0.5328 (3)0.31678 (16)0.0555 (10)
H13A0.10690.53360.27870.083*
H13B0.30240.47520.31970.083*
H13C0.31620.58630.31840.083*
C210.5941 (7)0.3702 (3)0.09550 (17)0.0572 (11)
H21A0.71190.40350.06810.086*
H21B0.66570.33690.12570.086*
H21C0.51650.32570.07260.086*
C220.2800 (6)0.5203 (2)0.07406 (15)0.0443 (8)
H22A0.40710.55460.05070.066*
H22B0.21310.47800.04740.066*
H22C0.16300.56430.09240.066*
C230.5452 (7)0.5329 (3)0.17392 (18)0.0563 (10)
H23A0.44070.57950.19470.084*
H23B0.61650.49790.20340.084*
H23C0.66420.56390.14570.084*
Atomic displacement parameters (Å2) top
U11U22U33U12U13U23
Cu10.0311 (3)0.0459 (3)0.0631 (4)0.0036 (2)0.0102 (2)0.0118 (3)
Cu2A0.0351 (4)0.0514 (13)0.0613 (13)0.0032 (7)0.0154 (7)0.0154 (8)
Cu2B0.0351 (4)0.0514 (13)0.0613 (13)0.0032 (7)0.0154 (7)0.0154 (8)
S10.0335 (5)0.0360 (5)0.0598 (6)0.0020 (4)0.0066 (4)0.0080 (4)
S20.0374 (5)0.0667 (7)0.0550 (6)0.0076 (4)0.0128 (4)0.0239 (5)
P10.0355 (5)0.0327 (4)0.0385 (5)0.0027 (4)0.0053 (4)0.0023 (4)
P20.0317 (4)0.0317 (4)0.0356 (4)0.0027 (3)0.0088 (3)0.0013 (3)
S30.0317 (5)0.0437 (5)0.0581 (5)0.0036 (4)0.0117 (4)0.0168 (4)
S40.0306 (4)0.0380 (4)0.0429 (5)0.0009 (3)0.0058 (3)0.0048 (4)
N30.0340 (17)0.0473 (18)0.0534 (18)0.0045 (14)0.0075 (14)0.0049 (14)
C30.0264 (17)0.0344 (17)0.0371 (17)0.0046 (14)0.0053 (13)0.0029 (14)
N40.0347 (17)0.0549 (19)0.0571 (19)0.0040 (14)0.0083 (14)0.0100 (15)
C40.0294 (17)0.0348 (18)0.0373 (18)0.0035 (14)0.0031 (14)0.0017 (14)
C110.066 (3)0.035 (2)0.097 (3)0.0106 (19)0.015 (2)0.009 (2)
C120.058 (3)0.068 (3)0.041 (2)0.007 (2)0.0039 (18)0.0054 (19)
C130.052 (2)0.072 (3)0.043 (2)0.005 (2)0.0114 (17)0.0016 (19)
C210.056 (2)0.060 (3)0.056 (2)0.024 (2)0.0123 (19)0.015 (2)
C220.051 (2)0.041 (2)0.0412 (19)0.0013 (17)0.0092 (16)0.0050 (16)
C230.055 (2)0.052 (2)0.065 (3)0.0013 (19)0.020 (2)0.011 (2)
Geometric parameters (Å, º) top
Cu1—N31.943 (3)S4—C41.654 (3)
Cu1—S12.2830 (11)N3—C31.150 (4)
Cu1—S32.3431 (11)N4—C41.154 (4)
Cu1—S42.6214 (12)C11—H11A0.9600
Cu1—Cu2B3.351 (5)C11—H11B0.9600
Cu1—Cu2A3.656 (3)C11—H11C0.9600
Cu2A—N4i1.894 (4)C12—H12A0.9600
Cu2A—S22.206 (3)C12—H12B0.9600
Cu2A—S42.316 (3)C12—H12C0.9600
Cu2B—N4i1.969 (6)C13—H13A0.9600
Cu2B—S22.315 (5)C13—H13B0.9600
Cu2B—S42.416 (5)C13—H13C0.9600
Cu2B—S12.702 (5)C21—H21A0.9600
S1—P11.9935 (13)C21—H21B0.9600
S2—P21.9848 (14)C21—H21C0.9600
P1—C131.783 (4)C22—H22A0.9600
P1—C111.783 (4)C22—H22B0.9600
P1—C121.791 (3)C22—H22C0.9600
P2—C231.784 (4)C23—H23A0.9600
P2—C221.788 (3)C23—H23B0.9600
P2—C211.790 (3)C23—H23C0.9600
S3—C3i1.648 (3)
N3—Cu1—S1133.19 (9)C4—N4—Cu2Aii169.9 (3)
N3—Cu1—S3109.10 (9)C4—N4—Cu2Bii166.1 (3)
S1—Cu1—S3108.66 (5)Cu2Aii—N4—Cu2Bii15.43 (11)
N3—Cu1—S498.56 (9)N4—C4—S4178.6 (3)
S1—Cu1—S498.61 (4)P1—C11—H11A109.5
S3—Cu1—S4103.37 (4)P1—C11—H11B109.5
N4i—Cu2A—S2137.01 (15)H11A—C11—H11B109.5
N4i—Cu2A—S4112.91 (14)P1—C11—H11C109.5
S2—Cu2A—S4108.98 (10)H11A—C11—H11C109.5
N4i—Cu2B—S2125.7 (3)H11B—C11—H11C109.5
N4i—Cu2B—S4106.2 (2)P1—C12—H12A109.5
S2—Cu2B—S4102.14 (18)P1—C12—H12B109.5
N4i—Cu2B—S1102.0 (2)H12A—C12—H12B109.5
S2—Cu2B—S1121.57 (19)P1—C12—H12C109.5
S4—Cu2B—S193.24 (16)H12A—C12—H12C109.5
P1—S1—Cu1105.99 (5)H12B—C12—H12C109.5
P1—S1—Cu2B113.21 (11)P1—C13—H13A109.5
Cu1—S1—Cu2B84.04 (11)P1—C13—H13B109.5
P2—S2—Cu2A106.09 (8)H13A—C13—H13B109.5
P2—S2—Cu2B106.55 (13)P1—C13—H13C109.5
C13—P1—C11107.1 (2)H13A—C13—H13C109.5
C13—P1—C12105.85 (18)H13B—C13—H13C109.5
C11—P1—C12107.5 (2)P2—C21—H21A109.5
C13—P1—S1113.33 (14)P2—C21—H21B109.5
C11—P1—S1109.55 (15)H21A—C21—H21B109.5
C12—P1—S1113.18 (14)P2—C21—H21C109.5
C23—P2—C22107.47 (18)H21A—C21—H21C109.5
C23—P2—C21106.22 (19)H21B—C21—H21C109.5
C22—P2—C21107.02 (17)P2—C22—H22A109.5
C23—P2—S2113.29 (14)P2—C22—H22B109.5
C22—P2—S2109.52 (12)H22A—C22—H22B109.5
C21—P2—S2112.98 (15)P2—C22—H22C109.5
C3i—S3—Cu1102.90 (12)H22A—C22—H22C109.5
C4—S4—Cu2B100.44 (16)H22B—C22—H22C109.5
C4—S4—Cu2A102.18 (13)P2—C23—H23A109.5
C4—S4—Cu197.27 (12)P2—C23—H23B109.5
Cu2B—S4—Cu183.30 (12)H23A—C23—H23B109.5
Cu2A—S4—Cu195.33 (10)P2—C23—H23C109.5
C3—N3—Cu1164.6 (3)H23A—C23—H23C109.5
N3—C3—S3ii178.8 (3)H23B—C23—H23C109.5
Symmetry codes: (i) x1, y, z; (ii) x+1, y, z.
Selected geometric parameters (Å, º) top
Cu1—N31.943 (3)Cu2B—N4i1.969 (6)
Cu1—S12.2830 (11)Cu2B—S22.315 (5)
Cu1—S32.3431 (11)Cu2B—S42.416 (5)
Cu2A—N4i1.894 (4)S1—P11.9935 (13)
Cu2A—S22.206 (3)S2—P21.9848 (14)
Cu2A—S42.316 (3)
P1—S1—Cu1105.99 (5)C4—S4—Cu2A102.18 (13)
P2—S2—Cu2A106.09 (8)C3—N3—Cu1164.6 (3)
P2—S2—Cu2B106.55 (13)C4—N4—Cu2Aii169.9 (3)
C3i—S3—Cu1102.90 (12)C4—N4—Cu2Bii166.1 (3)
C4—S4—Cu2B100.44 (16)
Symmetry codes: (i) x1, y, z; (ii) x+1, y, z.

Experimental details

Crystal data
Chemical formula[Cu(NCS)(C3H9PS)]
Mr229.75
Crystal system, space groupMonoclinic, P21/c
Temperature (K)298
a, b, c (Å)5.793 (3), 14.091 (3), 22.064 (7)
β (°) 98.945 (17)
V3)1779.2 (11)
Z8
Radiation typeCu Kα
µ (mm1)8.73
Crystal size (mm)0.31 × 0.06 × 0.05
Data collection
DiffractometerPicker 4-circle
Absorption correctionGaussian
(Busing & Levy, 1957)
Tmin, Tmax0.433, 0.704
No. of measured, independent and
observed [I > 2σ(I)] reflections
6315, 2912, 2144
Rint0.058
(sin θ/λ)max1)0.579
Refinement
R[F2 > 2σ(F2)], wR(F2), S 0.027, 0.076, 0.79
No. of reflections2912
No. of parameters174
H-atom treatmentH-atom parameters constrained
Δρmax, Δρmin (e Å3)0.29, 0.31

Computer programs: Corfield (1972), Data reduction followed procedures in Corfield et al. (1973) with p = 0.06, with programs written by Corfield and by Graeme Gainsford, local superposition program (Corfield, 1972), SHELXL97 (Sheldrick, 2008), ORTEPIII (Burnett & Johnson, 1996).

 

Acknowledgements

I am grateful for the provision of a crystalline sample by Jack A. Tiethof and Devon W. Meek, as well as assistance from Richard A. Kershaw and students of the 1972 Chem675 Crystallography Course at the Ohio State University, where the experimental work was carried out. The diffractometer was provided through partial support from the National Science Foundation equipment grant GP8534.

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