5366
tion around the aluminum atoms may be explained by considering the electrostatic repulsion between pairs of bonding electrons. Since oxygen is more electronegative than carbon, the AI-C bonding electron pairs are closer to the aluminum atom than the more strongly polarized AI-0 bonding pair. Thus the C-A1-C angles become larger (1 16-1 17 ") and the C-AI-0 angles become smaller ( 100") than the tetrahedral value. Figures 2 and 3 show the molecular structure of [AI( CH&I2.C4H8O2and packing in the crystals, respectively. Three-coordinate oxygen is usually found in a pyramidal configuration; a n exception is reported" for tetramethyl-0,O '-bistrimethylsilylcyclodialuinoxane, where the three oxygen valencies are coplanar. I n the present study, the AI-0-C(1) angle (122") and the (17) P. J. Whzatley, J . Chem. Soc., 2562 (1963)
C(1)-0-C(1) angle (108") are not what would be expected on the basis of sp3 hybridization for the oxygen atoms, nor d o they indicate that the oxygen is in a planar configuration. The nmr spectra using tetramethylsilane as an internal standard indicate a chemical shift of T 10.93 for the protons of the (CHJaAl- group. This suggests a higher electron density at these partly negative carbon atoms than is found at the terminal carbon atoms in the trimethylaluminum dimerIa ( T 10.67). The protons on the dioxane ring carbon atoms in the complex are in resonance at lower fields with a chemical shift of T 6.19 compared with the protons in p-dioxane (7 6.30). Acknowledgment. The support of the National Science Foundation is gratefully acknowledged. (18) N. Muller and D. E. Pritchard, J . An?. Chem. Soc., 82, 248 ( 1960).
A Compound Containing a Tetrahedral Cluster of Nickel Atoms' M. J. Bennett, F. A. Cotton, and B. H. C. Winquist Contribution from the Department of Chemistrj., Massachusetts Institute of Technology, Cambridge, Massachusetts 02139. Receioed May 6, 1967
Abstract: The crystal structure-and simultaneously the true empirical and molecular formulas-for a compound, Ni,(CO),[P(C,H,CN),],, first reported but incorrectly formulated in 1959, has been determined. The compound crystallizes in the space group R3 with hexagonal unit cell dimensions a = 18.78 0.02 A and c = 26.12 =E 0.02 A , and six formula units per cell. The molecules have nearly perfect tetrahedral symmetry aside from small deformations attributed to packing effects, although, crystallographically, only CI symmetry is required. In the tetrahedron of nickel atoms the mean Ni-Ni distance is 2.508 r 0.004 A. There is a symmetrical bridging carbonyl group across each edge of the tetrahedron and a P-Ni bond collinear with each threefold axis of the tetrahedron. A qualitative discussion of the bonding would suggest that the molecule should be inherently diamagnetic. Observed paramagnetism is thus attributed to contamination by nickel metal and other magnetic impurities in bulk samples of this rather unstable substance. _t
s
ome years ago Meriwether, Colthup, Fiene, and Cotton2 reported that the reaction of nickel carbonyl with tris(fl-cyanoethyl)phosphine, r(CH2CH2CN)3,led not only to the expected product of the Ni(C0)?(PR3)' type, which may be obtained with phosphines generally, but also to a red-orange product (mp 160" dec) containing less C O and less phosphine per metal atom. This compound, which was then formulated as [Ni(CO)P(C2H4CN)a],, was found to have n o infrared absorption attributable to terminal CO groups but it did exhibit one strong band at 1815 cm-'. Moreover, only a single C=N stretching band was observed at 2245 cm-', suggesting that none of the cyano groups was coordinated. It was also reported that the substance was paramagnetic, but with less than one unpaired electron per metal atom. It was suggested on the basis of this evidence that the substance was likely to be a polymer of some sort, either linear or
cyclic, with the polymerization number, 71, equal to at least 2. In the years since this preliminary study was reported, the widespread occurrence of metal atom cluster compounds in genera13a'4and those of the polynuclear metal carbonyl typezb in particular has been recognized. This prompted a reconsideration of the nature of this substance, Since it did form crystals, albeit rather unstable ones, a reinvestigation of it was undertaken using, as the principal tool, single-crystal X-ray diffraction. As will be seen, the compound has now been shown to have the formula Ni,(C0),[P(C2H,CN),], and to contain a tetrahedral cluster of nickel atoms.
( I ) This \vork was supported, i n part, by Contract No. AT(30-111965 with thc U. S. Atomic Energy Commission. (2) L. S. Meriwetlier, E. C. Colthup, M. L. Fiene, and F. A. Cotton, J . l i i o r g . .Virci. Chem., 11, 181 (1959).
(3) Cf. F. A. Cotton and G. Wilkinson, "Advanced Inorganic Chemistry," 2nd ed, Interscience Publishers, John Wiley and Sons, Itlc., New York, N.Y . , 1966: (a) p 656; (b) p 719. (4) F. A. Cotton, Quorl. Rec. (London), 20, 389 (1966).
Journrrl oftlie American Chemical Society
1
89.21
Experimental Section Crystals of Nir(CO)b[P(CH?CH2CN)3]4 were prepared by a modification of the method of Xleriwether, ei 0 1 . ~ Dry methanol (75
October 11, 1967
5367 ml) was distilled into a flask containing 2.9 g (0.015 mole) of tris(2-cyanoethy1)phosphine. The mixture was heated to reflux temperature, and 2.75 ml (0.022 mole) of Ni(CO)* dissolved in 50 ml of methanol was added slowly. Soon after addition of the Ni(C0)4 was initiated white, crystalline Ni(CO)?[P(CH2CH2CN)& precipitated with evolution of CO. The reaction mixture was then allowed to stand for 24 hr at 70” after which time small orange crystals of Ni4(CO)G[P(CHrCH2CN)3]4 had formed. Many of the crystals grew o n the surface of the magnetic stirring bar in the reaction flask. The stirring bar was carefully removed from the flask and stored in a vial under liquid nitrogen to reduce the rate of decomposition of the crystals. Suitable crystals for X-ray study were then selected from the stirring bar. When quantities of the compound other than single crystals are desired, it is necessary to remove the N~(CO)?[P(CHZCH.CN)~]* which is also formed in the reaction. The most satisfactory method found was to dissolve the contaminant in hot methanol, in which the cluster compound is insoluble, However, even after repeated purification, very weak bands of the impurity were still present in the infrared spectrum. Solubility. The compound is insoluble in most organic solvents and only slightly soluble in acetonitrile and acetone. These solutions undergo slow decomposition even in the absence of air Infrared Spectrum. A mull spectrum of Ni4(CO)s[P(CH2CH2CN)Jr in Nujol has absorption bands at 2239 (medium) and 1802 cm-1 (strong). They correspond to the C-N stretching frequency of the tris(2-cyanoethy1)phosphine and the C-0 stretching frequency of the bridging carbonyl? respectively. Very weak bands from the Ni(CO)2[P(CH2CHrCN)&were also present in the spectrum. Magnetic Properties. Magnetic measurements were made by the Gouy method. The magnetic susceptibility was measured at temperatures from 80 to 305°K and at field strengths from 2000 to 6700 oersteds, A considerable field dependence was observed over the range of field strengths, suggesting the presence of a ferromagnetic impurity. Nickel metal has been observed in the reaction flask during preparation of the compound, very likely resulting from the decomposition of Ni(C0)4 or the disubstituted carbonyl. The insolubility of the cornpound has prevented the removal of the ferromagnetic contamination. The nonlinearity of the CurieWeiss plot over a temperature range of 80-305X prevents any meaningful calculation of the magnetic moment. A mean value of xS = 1.64 x 10-6 was found at 19” which is close to that (1.8 X 10V) found previously. * An attempt was made to determine the magnetic behavior in acetone solution by observing the proton magnetic resonances of the cyanoethyl groups. but a saturated solution was too dilute to produce an observable resonance. Collection and Reduction of X-Ray Data. Single crystals were examined by precession photography and were found to belong to the rhombohedral system. The reflections were indexed with reference to hexagonal axes in the obverse rhombohedral setting. The space group extinctions are - A k I = 3n. The diffraction symmetry indicated the space group t o be R3 (No. 146) or RS (No. 148) with unit cell dimensions a = 18.78 i 0.02 A and c = 26.12 + 0.02 A. (The rhombohedral cell dimensions are u 13.89 A and a = 84.98”.) The density measured (by flotation) in aqueous barium iodide solution is 1.45 glee. uhich agrees well with the calculated density of 1.47 gicc for six molecules per hexagonal unit cell. The compound was found to decompose rather rapidly on exposure to the X-ray beam, and it was thereforeconsidered that threedimensional data could not be satisfactorily collected by photographic methods. Initially, an attempt was made to determine heavy atom (Ni, P) positions using two-dimensional precession data from the hkO and Okl zanes. To decrease the error introduced by decomposition of the compound, different crystals were used for collecting data from each zone. For each, a series of timed photographs was taken. However, when these data were read, it became apparent that considerable decomposition had occurred, and reduction of the data was not deemed worthwhile. The rate of decomposition of the crystals suggested, however, that a useful set of intensities could be collected by counter methods. Intensity data were thus collected at room temperature on a G.E. XRD-5 diffractometer using nickel-filtered Cu K a radiation. The intensities were monitored with a scintillation counter with the pulseheight discriminator set fer 95 % with the window centered on cuK~ radiation. Three single crystals, each in the fGrm of a Parallelepiped, were mounted with [W11 parallel to the 9 axis ofthe diffractometer. Reflection intensities were recorded from each crystal until the intensities of two standard reflections 0, 1, 2 and 1, 10, 0
+ +
7
decreased by approximately 10% of their original value, at which time a new crystal was mounted and data collection continued. The moving crystal-moving counter method of Furnass was used, but so modified that background counts were taken at the maximum and minimum values of 28 for each scan. The diffraction characteristics of the crystals indicated that a 40-sec scan of 2.66” would adequately record the integrated intensities. The intensity of each reflection is given by the total number of counts during the scan minus the sum of the two 20-sec background counts. All independent reflections (1860) within the range Ocu 5 50.4” were measured. The diffractometer settings and Lorentz-polarization corrections were calculated with Shoemaker’s MIXG-2program.6 The intensities were reduced to iFi,al’ and ‘F,i,lz by Elder’s program, RAWRE-2.‘ Solution of the Structure. For the purpose of calculating the Patterson function, all reflections from the three crystals were put on a single scale based upon the intensities of ten reflections which had been measured from each crystal. The possible positions of the general nickel and phosphorus atoms were found from the Harker plane ( x , y , 0). Vectors from each of these nickel atoms to the nickel atom on the threefold axis indicated the presence of tetrahedral arrangements of the metal atoms and, further, that adjacent tetrahedra on a threefold axis are related by a center of sqmmetry. It was not apparent from the Patterson map that the phosphorus atoms were also related by a center of symmetry, since vectors between center-related phosphorus atoms were either much weaker than other phosphorus-phosphorus vectors or did not appear. However, after a series of trial-and-error Fourier electron-density maps phased on the nickel atoms and an incomplete set of phosphorus atoms had been studied, it was seen that each phosphorus atom was actually related to another by a center of symmetry. Two successive difference Fourier maps then revealed the positions of all the remaining atoms and indicated that the proper space group was R3. The subsequent successful refinement of he structure has substantiated this choice. A structure factor calculation based on the atom positions found from the difference Fourier map had the residuals
For the refinement, all reflections were rejected for which ~-~ v‘(P $- B)/(P - B ) > 0.5, where P is the number of counts measured during the scan, and B is the total background count. Of a total of 1860 reflections measured, 843 were rejected using the above criterion. The atom coordinates, three scale factors, and isotropic atomic thermal parameters were refined by a full-matrix, least-squares procedure, minimizing Z w [ F,,; - ~ F C ~ l Atomic-scattering 2. factors for neutral Ni: P, C, N, and 0 used are those given by Ibers.8 The real and imaginary terms for Ni and P9 arising from anomalous dispersion were included in calculating the structure factors.10 No correction was made for absorption of X-rays by the crystals, since prmaxwas less than 0.15 ( p = 18.7 cm-1 for Cu K a radiation), After four cycles of isotropic least-squares refinement, the residuals R1and R2 decreased to 0.114 and 0.1 33, respectively, Since a unit weighting scheme has little justification in practice, an attempt was made to introduce a scheme more closely related to the experiment in which the weight, w , of each reflection is approximated by the expression [0.95 - 0.195iF0’~ 0.038~F,’2]-1. Applying this expression, another cycle of refinement resulted in values of R, = 0.107 and RP = 0.127. The weighting scheme was then checked by plotting [ ~ F o i ‘FC,l2 as a function of IFo!. It was found that the weighting scheme would be more satisfactorily __-~
+
(5) T. G. Furnas, Jr., “Single Crystal Oricnter Instruction Manual,” X-ray Department, General Electric, Schenectady, N. Y., 1957. . (6) D. P. Shoemaker, “MIXG-2, .M.I.T. X-ray Goniometer Package,”
__ 19(674).R. c. Elder, Ph.D. Thesis, Massachusetts Institute of Technology. 1y6L,
(8) J. A. Ibers in “IIlternational Tables for X-ray Crystallography,” VOI. 111, I 12.0, w = 12/(3.3 1.151F0’!). In the expressions for the weight of a reflection, F,’ is related to the structure amplitude on an absolute scale, IF,l, by IF,’l = 1/31F01 X (scale factor). A further cycle of refinement produced R1 = 0.107 and R2 = 0.112. In order to determine the effect of crystal decomposition on the data, the reflections were groupedaccording to the crystal fromwhich each was obtained. Each group was then used separately as data for a cycle of refinement in which only the scale factor and an overall temperature factor Bo were allowed to vary. The initial value of Bo was set at 2.0 A2, which also was subtracted from each atomic thermal parameter. The initial and final values of the parameters are shown in Table I. The small divergence in the three over-all temperature factors indicates that the effect of decomposition was practically equivalent for the three crystals, and it is clear from the behavior of the scale factors that no compensation was necessary to bring the three sets of data to a common scale other than individual scale factors.
+
Figure 2. A perspective view of the Ni4(CO)6[P(CH2CHzCN)3]4 molecule. Numbering of atoms corresponds to that in Tables I1 and IV-VI.
Description of the Structure A crystal of Ni4(CO)G[P(CH2CH2CN)3]4 is composed of distinct molecules stacked along the threefold axis of the space group with adjacent molecules in the stack related by a center of symmetry. Table 11. Final Atom Coordinates and Thermal Parameters“
Ni(1) Ni(2) P(1)
Table I. Refinement of Over-all Temperature Factor and Scale Factor for Data Sets from Three Crystals Crystal
-Bo, Initial
A2Final
-Scale Initial
factor-Final
1 2 3
2.00 2.00 2.00
1.98 2.04 1.97
0.232 0.281 0.307
0.232 0,283 0.306
The final cycle of refinement using all the data produced no change in the residuals: RI = 0.107, RZ = 0.112. The largest parameter shift in the last cycle was 1/4thof its estimated standard deviation. The largest feature on a difference Fourier map calculated from the final atom positions was a peak of 1.2 e/A3 near atom C(8). This together with the high temperature factors and poor bond lengths associated with atoms C(7) and C(8) suggest some disorder in this cyanoethyl chain. The final atomic positional and thermal parameters and their estimated errors are listed in Table 11. The estimated standard deviations were calculated from the usual least-squares formula, u 2 ( j ) = a,,(ZwAZ)/(m - n), where a j j is the appropriate element of the matrix which is inverse to the normal equation matrix. The observed and calculated structure amplitudes times 12 are listed in Table 111. Fourier and least-squares programs used in the calculations were M I F R - 2a ~modification , of Sly, Shoemaker, and Van den Hende’s Fourier program, and Prewitt’s full-matrix least-squares crystallographic program SFLSQ-3. l2 (1 1) W. G. Sly, D. P. Shoemaker, and J. H. Van den Hende, “A Twoand Three-Dimensional Fourier Program for the IBM 709,7090, ERFR-2,” 1962. (12) C. T. Prewitt, “A Full-Matrix Crystallographic Least Squares Program for the IBM 709/7090,” 1962.
Journal of the American Chemical Society
1 89:21 J October
0.0 0.08495 (16) 0.0 0.20235 (30) -0.0066 (11) 0.0513 (11) 0.0451 (14) 0.2978 (15) 0.2913 (18) 0.3764 (15) 0.2249 (15) 0.1582 (19) 0.2025 (31) 0.2305 (11) 0.2321 (12) 0.1501 (14) 0.1136 (11) 0.0234 (13) 0.0425 (13) 0.4375 (20) 0.2084 (1 8) 0.0878 (13) 0.1721 (8) 0,0363 (7)
0.0 0.06592 (16) 0.0 0.15951 (31) 0.0841 (11) 0.1675 (11) 0.2313 (14) 0.1704 (16) 0.0895 (18) 0.1067 (21) 0.1571 (15) 0.1457 (19) 0.1668 (30) 0.2688 (11) 0.2977 (12) 0.2821 (13) 0.0825 (11) 0.1101 (13) 0.2811 (14) 0.1114 (18) 0.1622 (18) 0.2701 (11) 0.1204 (8) 0.1686 (7)
0.21778 (18) 0.29606 (11) 0.13493 (31) 0.32556 (20) 0.1012 (6) 0.1254 (7) 0.0995 (9) 0.2982 (9) 0.2929 (11) 0.2741 (12) 0.3916 (9) 0,4235 (13) 0,4820 (22) 0.3195 (7) 0,2651 (8) 0.2487 (8) 0,2260 (7) 0.3247 (8) 0.0750 (8) 0.2635 ( 1 1 ) 0.5218 (13) 0.2360 (7) 0.1991 (5) 0.3504 (5)
2.9 (1) 3 . 0 (1) 3 . 2 (2) 3 . 6 (1) 4 . 2 (4) 4 . 2 (4) 6 . 2 (6) 7 . 6 (6) 9 . 5 (7) 11.1 (10) 7 . 2 (6) 10.0 (8) 17.6 (17) 4 . 2 (4) 4 . 8 (4) 5 . 4 (5) 4 . 2 (4) 5 . 6 (5) 8 . 8 (6) 12.6 (8) 1 2 . 2 (8) 6 . 7 (5) 5 . 3 (3) 4 . 2 (3)
Numbers in parentheses are estimated standard deviations and occur in the last significant figure for each parameter.
The closest intermolecular contacts are between cyanoethyl chains of neighboring molecules. The shortest of these, 3.21 A, is between the nitrogen atom of one chain and a methylene carbon atom of another. All contacts up to 4.5 A have been c a l c ~ l a t e d ,and ~~ pertinent values are listed in Table IV. A projection of the complete molecule down the c axis is shown in Figure 1. A perspective drawing, in (13) D. P. Shoemaker, “DtSTAN-CryStallOgraphiC Bond Distance, Bond Angle, and Dihedral Angle Program,” 1963.
11, 1967
5369 Table 111. Observed and Calculated Structure Amplitudes Times 12 H -3 b 12
1
-2 4 -5 7 10 -1
K fOBS fCAL 6 486 753
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6 1257 6 887 7 1221 7 1612 7 1160 7 589 1 987 7 806
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11 11 11 11 -3 12 -6 12 -9 12 -2 13 i 13 -5 13 -11 13 -1 1 * -7 Ir -10 1 * -3 15 -6 15 -5 16 2 -4 -7
637
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0
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15 1
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1
870
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1253 770 401 975 142 664 1028 5682 6014 1551 1664 1076 1088 408 426 1737 1569 2211 2 3 7 6 1163 iiai 3185 3237 13i9 1415 1181 1066 987 894 911 13b 952 952 1509 1b76 1239 1075 830 6L3 711 *9* 2403 2235 925 785 1610 1*91 927 736 l O L b 1138 2577 2716 1061 980 2 3 8 9 2378 1533 1370 1110 1195 1157 1101 1561 l51L 2000 2254 227* 3160 z 3 n v 2219 2131 2189 8OI 651 I903 lBli 812 812
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which six of the cyanoethyl chains are omitted for clarity, is presented in Figure 2. The intramolecular bond lengths and bond angles14 and their estimated standard deviations are listed in Tables V and VI. The molecule contains a tetrahedral cluster of nickel atoms with phosphorus-bonded tris(P-cyanoethy1)phosphine ligands at the apices and bridging carbonyl groups at the edges of the tetrahedron. The space group requires the molecule to have threefold symmetry, but it is only slightly distorted from tetrahedral symmetry with the exception of the arrangement of the cyanoethyl chains of the phosphine ligands. Each nickel atom interacts with seven neighboring atoms forming bonds with three nickel atoms, three carbon atoms, and one phosphorus atom. The average nickel-nickel bond length is 2.508 f 0.004 A, and the values of the two crystallographically independent types differ by an amount (0.0056 A) of the order of only one estimated standard deviation. Consequently, (14) J. S. Wood, "MGEOM, A Molecular Geometry Program for the IBM 7094," Massachusetts Institute of Technology, 1964.
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within experimental error the nickel atom cluster has undistorted tetrahedral symmetry. The average nickel-phosphorus bond length is 2.161 0.005 A, and the tetrahedral symmetry is slightly distorted by the phosphorus atoms. The interatomic distance between phosphorus atoms related by the threefold axis is 6.008 f 0.011 A, and the distance from one of these to the phosphorus atom on the threefold axis is 6.067 f 0.008 A ; thus there is a slight elongation of the tetrahedron composed of phosphorus atoms. Since there is no apparent chemical reason for it, this distortion is assumed t o be due t o intermolecular forces in the crystal. The tetrahedral symmetry of the molecule is further destroyed by the arrangement of the cyanoethyl chains. Those attached to the phosphorus atom in the special position (on the threefold axis) are related by the threefold axis. However, those on the three phosphorus atoms which occupy general positions have no internal symmetry. Thus the chain composed of atoms C(lO), C(11), and C(12) folds back toward the molecule, while the other two
*
Bennett, Cotton, Winquist
1
Crystal Structure o f Ni4(CO)6[P(C2H4CN)3]4
5310 Table IV. Intermolecular Contacts
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31
Atom in given molecule
Atom (2) in neighboring molecule
C(1) C(1) C(2) C(3) C(4) C(4) C(5) C(5) C(6) C(6) C(7) C(7) C(8) C(8) C(9) C(9) C(9) C(9) C(l0) C(10) C(10) C(10) C(11) C(11) C(11) C(12) N(1) N(2) N(3) N(3) N(3)
N(2) N(2) N(2) N(2) N(1) N(1) C(10) N(1) N(1) C(10) N(1) N(2) N(3) N(3) C(9) N(3) C(8) N(3) C(12) N(4) O(2) N(1) N(3) O(2) N(1) N(3) N(2) O(1) N(3) N(4) O(2)
Table VI. Bond Angles, Degrees Interatomic distance, A
Coordinates of atom (2) relative to those of same atom in given molecule (Y
-
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Atoms forming angle
Angle, deg 60.15 59.93 144.64 146.22 143.00 145.01 82.2 137.4 140.3 84.6 137.6 137.8 118.1 119.5 118 9 118.7 111.0 110.4 111.5 114.8 110.5 105.7 101.5 111.5 174.2 171.9 158.9 179.6 96.4 96 9 95.8 96.9 99.6 98.5 99.8 97.0
Est std dev 0 . I7 0.09 0.32 0 . I8 0.20 0.20 0.7 1.5 1.5 0.9 1.7 1.7 0.7 0.8 0.8 0.6 1.2 1.8 1.9 1.3 1.6 2.4 2.9 1.6 2.4 3.4 4.8 2.2 0.6 0.6 0.7 0.7 0.9 1.1 1 .o 1 .o
Table V. Bond Distancese Bond
Distance, A
Ni( 1)-Ni(2) Ni(2)-Ni(2) ' Ni( 1)-C( 13) Ni(2j C ( 1 3 ) Ni(2)-C(14) Ni(2)'-C(14) Ni( l)-P( 1) Ni( 2)-P( 2) C(13)-0(1) C( 1 4 t 0 ( 2 ) P( 1t C ( 1) ~(2)-c(4) ~(2)-c(7)
2,506 ( 5 ) 2.512 (6) 1.922(18) 1.889(19) 1.881 (22) 1.852 (22) 2.163 (IO) 2 . I61 (6) 1.194(23) 1,206 (25) 1.866(19) 1.844 (25) 1.783 (25)
Bond
Distance, A
P(2)-C(10) C(I)-C(2) C(4)-C(5) C(7)-C(8) C(lO)-C(11) C(2)-C(3) C(5)-C(6) C(X)-C(9) C(ll)-C(12) C(3)-N(1) C(6)-N(2) C(9tN(3) C( 12)-N(4)
1.852 (19) 1 . 5 3 (3) 1 47 (4) 1 , 4 3 (4) 1.52(3) 1.43 (3) I , 54 (5) 1 .69 (7) 1 .48 (3) 1.16 (3) 1 . 1 4 (5) I .05 (7) 1.12 (3)
The bond lengths found between other atoms of the cyanoethyl groups are close t o those expected with the exception of that group composed of atoms C(7), C(8), C(9), and N(3), which shows evidence of disorder. Thus the bond lengths and errors calculated for these atoms are not considered reliable. There is no evidence that any coordination of the nickel atoms by nitrogen occurs. The closest nickelnitrogen distance is 4.12 A between N(4) and Ni(2). The bridging carbonyl groups are symmetrical; each carbon atom is equidistant, within experimental uncertainty, from each of the two nickel atoms to which a Numbers in parentheses are the estimated standard deviations it is bonded. The mean of these Ni-C distances is and occur in the last significant figure of each bond length. 1.890 i 0.003 A. This figure is similar to those found in other cases, e.g., in dicobalt octacarbonyl'j (1.92 f 0.01 A) and [(CjH,)Fe(CO)s]2'6(1.85 =I= 0.03 A). chains extend out from the nickel cluster. The arThe average carbon-to-oxygen distance, 1.20 f 0.02 rangement of the carbon chains appears to be the result A, is quite comparable to those'5a16(1.20 f 0.02, 1.21 of interatomic repulsions, particularly those between i 0.04 A) found in similar cases. the C(lO), C(ll), C(12) chain of one molecule and that Ideally, that is, for perfect tetrahedral symmetry, composed of atoms C(1), C(2), C(3), and N ( l ) located the six carbon atoms and the six oxygen atoms would at ( 2 / 3 x - y, x, 1/3 z) in the neighboring each define a regular octahedron. There is, however, molecule. Atom N ( l ) approaches within 3.21 A minor distortion which takes the form of a slight bendof C( 11) in the folded chain. ing of some of the CO groups out of the plane defined Bond angles involving atoms Ni-P-C(a) and C(a)by the two nickel atoms to which they are bonded and P-C'(a) have been calculated and are shown in Table the midpoint of the opposite edge of the tetrahedron of VI. The average Ni-P-C(a) angle is 118.7 * 0.4", which is within the range, 114-120", commonly found (15) G.G.Sumner, H.P. ]