Preparation and properties of dinitrogen-molybdenum complexes. 6

6. Syntheses and molecular structures of a five-coordinate molybdenum(0) ..... Molecular hydrogen complexes: coordination of a .sigma. bond to transit...
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Hidai et al.

/ Mo(CO)(N~)(P~~PCH~CH~PP~~)~.~/~C~H~

H. M. Pohlit, T. H. Lin, W. R. Erwin, and R. M. Lemmon. J. Am. Chem. SOC., 91, 5421 (1969); J. Phys. Chem., 75, 2555 (1971). G. M. Jenkins and D . R . Wiles, J. Chem. Soc., Chem. Commun., 1177 (1972). H. D. Hagstrum, Phys. Rev., 96, 336 (1954); 150, 495 (1966); 119, 940 (1960); Surf. Scl., 54, 197 (1976); Metals, 6, 309 (1972). H. D. Hagstrum. Phys. Rev., 122, 83 (1961). H. F. Winters and D . E. Horne, Surf. Sci., 24, 587 (1971); H. F. Winters, J. Appl. Phys., 43, 4809 (1972); H. F. Winters and P. Sigmund, ibid., 45, 4760 (1974). G. M. Lancaster, J. A. Taylor, A. Ignatiev, and J. W. Rabalais, J. Electron Spectrosc. Relat. Phenom., in press. F. R. McFeely, S. P. Kowalezyk, L. Ley, R . G. Cavel, R. A. Poliak, and D. A. Shirley, Phys. Rev., 9, 5268 (1974). C. R. Ginnard and W. M. Riggs, Anal. Chem., 44, 1310 (1972). R. F. Willis, B. Fitton, and G. S. Painter, Phys. Rev. Sect. 6, 9, 1926

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(1974). (18) P. M. Williams, D . Latham, and J. Wood, J. Electron Spectrosc. Relat. Phenom, 7 , 2 8 1 (1975). A. M. Bradshaw and U. Krause, Verlag Chem., 1095 (1975). G. Henning, J. Chem. Phys., 19, 922 (1951); M. L. Dzurus and G. R. Henning, J. Am. Chem. SOC., 9, 1051 (1957); G. Henning, J. Chem. fhys., 20, 1438 (1952); H. Selig, P. K. Gallagher, and L. B. Ebert, inorg. Nucl. Chem. Lett., 13,427 (1977); M. E. Vol'pin, Yu. N. Nivokov, N. D. Lapkina, V. I. Kasatochkin, Yu. T. Struckhov, M. E. Kazahov. R. A. Stukan, V. A. Povitskij, Yu. S. Karimov, and A. V. Zuarikina. J. Am. Chem. SOC., 97, 3366 (1975). V. Franchetti, B.H. Solka, W. E. Baitinger, J. W. Amy, and R. G. Cooks, Int. J. Mass. Spectrom. /on Phys., 23, 29 (1977). The projected range is defined as the mean penetration depth for ions traveling normal to the surface; see P. D. Townsend, J. C. Kelly, and M. E. W. Hartley, "Ion Implantation, Sputtering, and Their Applications", Academic Press, New York, N.Y., 1976.

Preparation and Properties of Dinitrogen-Molybdenum Complexes. 6. Syntheses and Molecular Structures of a Five-Coordinate Mo(0) Complex M o ( C O ) ( P ~ ~ P C H ~ C H and ~ P Pa ~ ~ ) ~ Related Six-Coordinate Complex MO( CO)( N2)(Ph2PCH2CH2PPh2)2*V$C6H6 Maki Sato,2aTakashi Tatsumi,2a Teruyuki Kodama,2aMasanobu Hidai,*2a Tokiko Uchida,2band Yasuzo UchidaZa Contribution f r o m the Department of Industrial Chemistry, Faculty of Engineering, Uniuersity of Tokyo, Hongo, Tokyo 113, Japan, and Department of Industrial Chemistry, Faculty of Science and Technology, Science Unicersity of Tokyo, Noda, Chiba 278, Japan. Receiued January 24, 1977

Abstract: The reaction of trans-Mo(N2)2(dpe)2 (dpe = PhzPCH2CH2PPh2) with benzyl propionate at reflux in benzene under dinitrogen yielded tr~ns-Mo(CO)(N2)(dpe)2.~/2C6H6. On bubbling argon gas into a solution of the latter complex, a stable five-coordinate complex Mo(CO)(dpe)z was obtained and this reaction was reversible. The structures of those two complexes have been determined from three-dimensional x-ray counter data. The complex Mo(CO)(dpe)z crystallizes in the monoclinic system with the space group P21/n, with the following cell dimensions: a = 17.849 (3). b = 24.295 (4), c = 10.939 (2) A; p = 99.1 17 (4)O, V = 4683.5 (13) A3, and Z = 4. The molybdenum atom has square-pyramidal coordination with four phosphorus atoms as a basal plane and an axial linear carbonyl ligand (average Mo-P = 2.452 (2) A, Mo-C = 1.903 (9) A, and C - 0 = 1.192 ( 1 2) A). The nearest hydrogen is 2.98 ( 1 1) A from molybdenum, suggesting van der Waals contact of the ortho hydrogen atom of one of the dpe phenyl groups with the metal. The complex Mo(CO)(Nz)(dpe)2.'/2C6H6 crystallizes in the monoclinic system with the space group C2/c, with the following cell dimensions: a = 48.50 ( 6 ) ,b = 11.07 ( I ) , c = 18.25 (2) A: p = 97.98 (3)O, V = 9699 (22) A3, and Z = 8. The molybdenum atom has octahedral coordination with average Mo-P = 2.448 (4) A, Mo-C = 1.973 (16) A, Mo-N = 2.068 ( 1 2) A, C - 0 = 1.1 27 (20) A, and N - h = 1.087 ( 1 8) A. Bond distances in two complexes are compared and discussed.

In a previous c o m m ~ n i c a t i o n ,we ~ briefly reported that a stable five-coordinate Mo(0) complex, Mo(CO)(dpe)Z (dpe = Ph2PCH2CH2PPh2) ( I ) , was obtained on bubbling argon gas into a benzene solution of trans-Mo(CO)(N2)(dpe)2. ]/2C6H6 (2) and this reaction was reversible. Since structural information on metal sites which have the capacity to bind dinitrogen as a ligand is strongly desirable, it seems of special interest to determine the molecular structure of 1. Furthermore, the five-coordinate M(0) complexes (M = Cr, Mo, or W ) are frequently postulated as the intermediates in Sy1 processes of six-coordinate group 6 metal complexes4 and the structures of such species have been extensively studied by trapping them in low-temperature solid mat rice^.^ Although a few examples of five-coordinate d6 complexes of Ru(I1) and Rh(II1) have been established by x-ray diffraction studies,6 none is, to the best of our knowledge, known for group 6 transition metal complexes.' W e wish here to report the synthesis 0002-7863/78/1500-4447$01 .OO/O

and the molecular structure of the first example of a stable five-coordinate d6 molybdenum complex 1, as well as of the dinitrogen complex 2.

Experimental Section All reactions were carried out under an atmosphere of pure dinitrogen or argon using purified dioxygen-free solvents and standard Schlenk-tube techniques. The complex trans- M o ( N ~ ) ~ ( d p e )was z prepared by the published method.8 Infrared spectra were recorded from KBr pellets using a Nihon-bunko IRA1 double-beam spectrometer. Preparation of trans-Mo(COXNzXdpe)2.l/zC6H6 (2). Method A. Dimethylformamide (DMF) (19.0 g, 0.26 mol) was added to a solution of trans-Mo(N2)2(dpe)2 (2.0 g, 2.1 mmol) in benzene (80 mL) under dinitrogen. The mixture was heated under reflux for 20 min, during which the orange solution had become dark red. After cooling, n-hexane (100 mL) was added and the precipitate formed was filtered off, washed with ether and n-hexane, and dried in vacuo to yield dark

0 1978 American Chemical Societj

4448

Journal of t h e A m e r i c a n Chemical S o c i e t y

Table 1. Summary of Crystal Data compd formula formula wt a, A

b, 8, C.

A

density, g/cm3 (calcd) systematic absences space group F(000) crystal dimensions cm-I maximum absorption effects

p,

/

100:14

Table 11. Summary of Intensity Collection and Refinement

Mo(CO)(dpe)z Mo(CO)(dPe)2 C53H480P4MO 920.8 1 17.849 (3) 24.295 (4) 10.939 (2) 99.117 (4) 4683.5 (13) 4 1.31 hOl, h I odd OkO, k odd

+

P21ln

1904 0.3 X 0.3 X 0.7 mm 4.5 27%

/ July 5, 1978

987.88 48.50, (6) 11.07 (1) 18.25 (2) 97.98 (3) 9699 (22) 8 1.35 khl, h k odd hOl, I odd c2/c 4088 0.1 X 0.7 X 0.6 mm

+

4.4 27%

red crystals of Mo(CO)(DMF)(dpe)z (1.6 g, 76%).9 Anal. Calcd for C56H5=,N02P4Mo: C, 67.7; H , 5.6; N , 1.4. Found: C, 67.1; H, 5.7; N , 1.3. When Mo(CO)(DMF)(dpe)z (1.6 g) was recrystallized from benzeneln-hexane under a dinitrogen atmosphere, dinitrogen replaced the D M F ligand from the complex to give orange crystals, which were separated, washed with n-hexane, and dried in vacuo to yield 2 (1 .O g, 63%). Anal. Calcd for C56HjlN~OP4Mo:C, 68.1; H, 5.2; N,2.8. Found: C, 67.9; H, 5.4; N , 3.2. The presence of benzene in 2 was checked by gas chromatographic analysis of a toluene solution of

2. Method B. Benzyl propionate (3.4 g, 21 mmol) was added to a solution of frans-Mo(N2)z(dpe)2 (2.0 g, 2.1 mmol) in benzene (60 mL). The mixture was heated under reflux for 30 min, during which the solution had become dark brown. On cooling under dinitrogen, the dark brown solution changed rapidly to orange. Addition of n-hexane (80 mL) deposited orange crystals, which were filtered off, washed with n-hexane, and dried in vacuo to yield 2 (1.1 g, 53%). When toluene was used as solvent instead of benzene, 2 was obtained similarly in a moderate yield (54%); however, in this case orange crystals of 2 were mixed with a small amount (3%) of yellow crystals of ci~-Mo(CO)z(dpe)2.~O Gas chromatographic analysis of the reaction system disclosed the formation of ethylene, ethane, and benzene as decarbonylated products. Preparation of Mo(C0Xdpe)z(1). Argon gas was bubbled through a solution of 2 (99 mg, 0.10 mmol) in benzene ( I O mL) at 50 'C for 3 min. The original orange color changed rapidly to dark brown. On addition of n-hexane (1 5 mL) to the resulting solution under an argon atmosphere, black crystals were formed, which were filtered off, washed with n-hexane, and dried in vacuo to yield 1 (48 mg, 52%). P ~69.1; M OH :, 5.2; N , 0.0. Found: C, Anal. Calcd for C ~ ~ H ~ ~ O C, 68.7; H , 5.3; N, 0.0. Reaction of Mo(COXdpe)2(1) with Dinitrogen. Under a dinitrogen atmosphere benzene ( 5 mL) was added to crystals of 1 (46 mg, 0.05 mmol). The moment the complex dissolved, the solution became orange. Addition of n-hexane ( I O mL) deposited orange crystals of frans-M0(CO)(N2)(dpe)2.~/2CgH6 (2, 37 mg, 75%). Reaction of Mo(C0Xdpe)z (1) with Carbon Monoxide. Carbon monoxide was bubbled through a solution of 1 (95 mg, 0.10 mmol) in benzene (IO mL) at room temperature. The color of the solution immediately changed to yellowish orange and after a few minutes n-hexane (1 5 mL) was added to deposit yellowish-orange crystals, which were filtered off, washed with n-hexane, and dried in vacuo to yield frans-Mo(CO)2(dpe)2 (29 rng, 30%) ( u (CEO) 1812 cm-1). Anal. Calcd for C54H4gOlP4Mo: C, 68.4; H , 5.1, N , 0.0. Found: C , 68.9; H , 5.0; N , 0.0. When the above reaction solution was allowed to stand for several hours and then n-hexane was added, the well-known compound cisMo(CO)z(dpe)210 was exclusively isolated as yellow crystals. Crystal Preparation. Dark red crystals of 1 and orange crystals of 2 were precipitated in the form of plates from benzeneln-hexane under argon and dinitrogen atmosphere, respectively, and were sealed in

used data (Fa 1 3 a F a ) total data 20 limits scan speed (28) scan length, min background weighting schemeo

R b (isotropic) R w C(isotropic) R (anisotropic) R , (anisotropic) R (final) R , (final) (I

Mo(COI(N2)(dPe)2 * 'hC6H6

7122

3606

13 341 20 I60' 2'/min 1 0.45 tan 0 measd for I O s a t each end of the scan w = 0.7 for IFoI < 19 w = 1.0 for 19 5 IF,l I 7 6 w = (76/1F01)2 for 76 < IF01 0.108 0.135 0.09 1 0.108 0.076 0.087

5496 20 5 42.5' 2'/min 1 0.45 tan 0 measd for 10 s at each end of the scan w = 0.7 for IFa(< 38 w = I .O for 38 5 lFol 5 76 w = (76/1F,1)2 for 76 < IF01 0.1 10 0.146 0.088 0.120 0.084 0.120

+

+

The scale of F, is approximately equal to absolute scale. R = - I F c I I / z I F o l . 'Rw = [xw(JFoI- I F ~ ( ) * / Z W I F ~ ) ~ ] ' / ~ .

ZIIFoI

Pyrex glass capillaries under the same atmosphere for x-ray data collection. Crystallographic Data. The crystals of 2 belonged to the monoclinic system with the absent spectra: hkl, h k odd; h01, I odd, that were characteristic of the centrosymmetric space group C2/c or the noncentrosymmetric space group Cc. The centrosymmetric space group was shown to be the correct one on the basis of the following results: (a) the acceptable positional parameters, thermal parameters, and agreement indexes in the successful refinements; (b) the clear and distinct location of all the 48 unique hydrogen atoms except solvent hydrogens in a difference Fourier map. Lattice parameters of both crystals were determined by a least-squares fit to the setting angles for 12 hand-centered reflections with 20' < 20 < 32' for the complex 1 and 16' < 20 < 3 1' for the complex 2 using the average of positive and negative 28 angles for Mo Kcu. Because of air sensitivity and good solubility of the complexes, only approximate densities, values of which were between those of chloroform ( d = 1.49) and glycerol (d = 1.26), could be observable by flotation. Table 1 shows the pertinent crystal information for both crystals. Data collection was carried out with LiF-monochromatized Mo Kcu ( A = 0.7107 A) radiation, using a Rigaku automated four-circle diffractometer by 28-w scan technique. Four standard reflections for each complex were monitored every 50 measurements to check any unfavorable effects. The systematic changes in the intensities were not observed. The variation of their intensities was within 2.3% for the crystal of 1 and 5.5% for the crystal of 2, respectively. Lorentz and polarization corrections were applied in the usual manner, but no absorption correction was made since maximum absorption effects (pR) are 0.63 and 0.62 for 1 and 2, respectively. Table I I shows the details of intensity collections and refinements of both crystals. Structure Refinement.]]The Patterson synthesis was used to locate the molybdenum atom for each complex. Subsequent Fourier syntheses revealed the positions of all the nonhydrogen atoms except the carbon atoms of the solvated benzene of the complex 2 because of the disorder of it. The structures were refined by block-diagonal leastsquares technique for nonhydrogen atoms first with isotropic thermal parameters, then with anisotropic thermal parameters. The quantity minimized was B w ( ( F , ( - I F c ( ) 2where in the case of 2, disordered benzene was neglected in F,.The atomic scattering factors were taken from the International TablesLzaand the anomalous terms for M o and P were those of Cromer and Liberman'2b and were included in F,. At this stage, difference Fourier syntheses showed clear peaks of hydrogen atoms of both complexes except those of the solvated molecule in the complex 2. Then we carried out block-diagonal least-squares calculations including the positional parameters of the hydrogen atoms,

+

4449

Table IIIa. Positional and Thermal Parameters for the

Table IVa. Positional and Thermal Parameters for the

Nonhydrogen Atoms of Mo(CO)(dpe)2

Nonhydrogen Atoms of Mo(CO)(N2)(dpe)r1/2C6H6

2

Y

no

iin!ii

ll051ll

135211j

247121

16712!

294121

PI11

1338111

1031111

2855121

335191

4151111

PI21

12961li

2120111

2778121

296181

410110~

4361101 iizia!

Pi31

1146111 3426111

*tern

'lib

'33

'12

'11

"23

10131

19121

4171

25111

-22181

3417)

-12161

-10171

46151

111161

-111171

341181

~ 1 8 1 -61161

316181

4lOliOI

0171

-3171

681151

4251101

350191 4201101

-15171

ioa18i

36171

32111

65161

311701

6170161

11541571

8451491

5601361

1271461

4151371

1471171

5161411

5651471

4241371

1271421

li1i321

1001391

3471691

4491.1

5861611

-76'621

5181841

1461581

7141901

-501581

1875141 2058141

1694141

5169171

103141

1362131

1955111

1291351

4881451

5661461

371lzr

451311

671361

c121

360141

1922111

2289171

5011411

361291

-371291

-621131

4189141

2017141

495711~

65:154!

4931431

11351

-17!31!

101181

CI41

4141141

1492131

4298181

2861321 3341361 3061351

4711411

c131

5461471

641i501

451321

-171331

5971481

4201441

4531421

451311

-121351

6551611

.3841139l

6861651

1471671

2111511

-1171681

c 1 1 1 1 1 1214151

875131

C l 1 1 2 1 1841161

988161 948111

1165171 5791101 -7201111

13151115 1

.1 7 1 6 1 1 1 2 1

6081681

C l 1 1 4 1 1105191

719161 -14251111

14691123 1 ,, 1 9 2 1 1 0 7 1

581(691

CI1151

501181

651161

-8681111

12431111 1 129111181

770180i

Cill61

2151105

1631921 -3061911

-8'701

891751

-441701

-41751

231691

-1ai6s, 691861

-661691 -18,571

721151

781158'

9101831

6 6 7 611 -1001621

359131

3600171

4091381

5251481

191'431

-140141

3C69191

856170'

59016C.

6751501

C11231

1306171

-645141

1 7 2 5 1 1 1 1 12281981

463159'

9 4 8 , 8 2 1 -15916:1

CIl24l

1109161

-642141

48851101

aio!w

6671681

6261731

-111571

3:1581

1141561

C11251

96616,

-154151

51121101

9111771

6651661

861173,

-651581

2451601

1961561

C11261 1 0 2 7 1 6 1

359141

47881101

8341681

5161541

7841661

-1149'

2551541

C l l l l i

919141

2868131

3739171

3121321

484'421

3891351

881291

CI2121

300151

1204141

izi)!ai

5601481

8241691

4761431

2211471

451321

-:91361

105,511

-241471

-61-11

-1071541

211811

671941 -121991

2441931 -521731

-541911

18,651

-511691

551781

-341751

951941

871991 691981

621901

1391481

18!1311 -771821

481271

-91311

2011831

-481361

-2031451

-22(1191

255110'11

10111241

59611131

-4311731

1967191

5141521

866170

351441 -2381541

3618141

5201191

6431561

izi1641

718!611 5581571

2591511

16615i

59148)

1831451 -2491491

3358141

5682 I71

862 1661

8111701

3791401

1001561

151401 -1591451

C12161 1261141

2952131

4955171

4951431

4861461

4361401

-31121

C I l 2 1 1 1173141

2719131

1351161

3311331

6271491

2801321

21151 241321

221251

391311

661761

C12221

1620161

3264141

1454181

9441701

saoiss!

5 4 4 1 4 8 1 -1131551

1781461

201471

1611901

C 0 2 3 1 1114181

3556151

7161691 -1441111

240!681

1621581

C l l 2 4 1 1685111

3292151

-711191

9161761

10941901

6061571

-981141

931521

2521651

1211161

Cl1251 1 4 7 l l l l

2157151

-839181

9181791

17011961

1511451 -1071701

121411

-331511

-41011071

C12161 1314151

2462141

428i101 i z i 5 ~ 1 0 5 1 i 4 2 1 7 4 1

216111

5251411

7241591

4261421

-1181431

151351

2614131

2708171

4081371

427141~

2878141

2776191

4841411

6941611

7021581

-69143,

1701421

241481

2959151

16651121

6371611

7781741

12991931

-391541

5381651

1181681

481311

1381301

2685122

80111131 1 6 0 7 1 2 5 6 '

38611661 - 5 9 2 1 1 5 9 1

1 1 8 6 2 1 3 1 1 6 2 5 1 2 8 6 1 268114111 - 4 6 6 1 2 0 4 1

-3'1131

-31311

C13141 4402171

2187151

5501111

10661911

9251841

9451831

20.71711

6251121

1161671

Cl3151

3731171

2520161

465191

10251881

132111061

4801561

1131801

2551561

1141631

CO161 3364161

2435151

1526181

1 1 6 5 1 2 6 8 1 -87512791 84011971 -74211991

-111411

C11131 0 9 2 1 6 1

4331381

25111111

2115130

-481341

C I l l Z l 4468151

C13111 3169141

1041.271

51951 501871

301(10l!

984161

3608141

-611681

-8711061

cIa1o

22151

2118OL -8oi631 -1611911

2081851

C11151

Cl2lll

1561591 -1401761

-291341

-3131141 -1621771

-128 5 1 1

39:69i

11671

1541641 -1B8166I

-111391

533161

-211341 331521

-271561

102,701

C l l 2 l 1 1218141 C i l l Z i 1364161

4~41101

-251601

4 8 ~ 1 7 3 1- 1 1 8 1 8 0 1 1011731

1c15,

lS$I?! 1011171

4065!21

0

CI1131 1771181

-916:

4055121

C O l CIlI

323161

16131

1183111

1086111 1683131

PI41

'22

171711

-1441851 -17111071 -9511071 4811041

-5aiazi

-13170

-981821

-198wii

-2541991

31991

-13511201

16111051

16011061

-8711141

18190

-41011211

881801

-1511851

111691

-1l8167i

1381611

9231141

3921431

Cl3211 3314141

3012131

4998111

3171341

6121501

4111E11

-61331

-221451 361291 - 1 5 2 0 7 1

1191851

321921

C13221

3235151

2941141

6755181

5481481

7011601

4911461

-501431

871371 -2191421

-571891

10311061

Cl323i

319316L

3409151

ioii1'1i

640!59!

105019i1

6931601

491581

5 9 1 4 1 1 -1221601

18811051 -19311051

C l 3 2 4 1 3209111

1925151

65241111

8311i61

1139!991

8071741

1151691

C13251 3267111

4005141

52941121

9681641

5211611

11731971

-161511

961721 - 1 7 3 1 6 1 1

-551881

C13261 3324161

3545141

4518191

7861651

5501551

6751581

711481

1281491

-891461

991691

591751

C14111 3561141

588111

2833171

4091371

3881381

1341381

621301

1131291

281311

611141

-461721

Cl4121

181141

1725181

5191451

5811521

5321461

-201391

1911311

201401

1211811

3171961

8171731

2451451

91481

2881961

249llOll

2141641 - 1 6 6 1 5 5 1 1401891 211531 1561601 41461

2461931

3786151

C l 4 1 3 1 3196161 C l 4 1 4 1 3590111

424141 -114151

C 1 4 1 5 1 3 3 7 5 1 1 0 1 -311151

C1416l

727181

7131601

1611551

5231511

-161541

127011001

1241121

6581631

-31691

18651111 198411531

5681701

8 1 6 ( 8 0 1 -223181)

5041531

8101101

151411

81591 - 5 1 9 1 6 9 1

3362181

41141

2890191

146611071

5681611

C14211 3 5 5 9 1 1 1 Cl4221 2 9 5 5 1 5 1

619131

5438161

5451431

474140

3111341

1051351

411301

501311

514141

6051191

5921531

6961631

195'641

1801471

2191411

3991521

9891851

9491681

1064i901

3211721

4411711

5451141

12151961

8061141

5101521

4031701

2551511

2131521

181581 1291441

422174)

Cl4211 3 0 4 1 1 7 1

114151

70481121

-891661

C14241 3103111

-141151

C l 4 2 5 1 4312161

-36161

67961101

8111131

135311131

8081141

5161761

C14261 4 2 3 7 1 5 1

350151

5836191

593155:

1201!97!

1921161

3441591

1319191

-011201

123071 601731

1051lOOl -1001931

151801 -111731 -1241641

-641811

-123091

-261981

-171196l

10011241

-641841

49411321

-411791

1351951

-131781

ir1215ai

while their isotropic thermal parameters were fixed at 6.0 A2. After the final refinement, the standard deviations of observations of unit weight [ 2 w ( ( F o (- IFc1)2/(mwere 3.41 and 10.7, respectively, where the numbers of reflections ( m )were 7 122 and 3606 and the numbers of refined parameters ( n ) were 725 and 743, respectively. In the final cycle, no parameter shifted by more than 0.3 of its estimated standard deviation. Analyses of w(JF,I as functions of setting angles, F,, and Miller indexes revealed that agreement was not good a t low angles of the complex 2.This is to be expected in view of our inadequate treatment for the rather ill-defined solvent molecule. The maximum densities in the final difference Fourier syntheses were 0.7 and 0.8 e / A 3 for 1 and 2, respectively. The positional and thermal parameters obtained from the last cycle of refinement are listed in Tables IIIa,b and IVa,b with the associated standard deviations estimated from the inverse matrix. A listing of the observed and calculated structure amplitudes used in the refinements is available.

Results and Discussion Synthesis of a Five-Coordinate Molybdenum(0)Complex Mo(CO)(dpe)2(1) from trans-Mo(N2)2(dpe)z.The molybdenum bis(dinitrogen) complex trans-Mo(N2)2(dpe)2 (3) reacts with

D M F in benzene at reflux to yield a dark red complex Mo(CO)(DMF)(dpe)z. The only other example of carbon monoxide abstraction from amides was found in a rhodium c0mplex.1~Infrared measurements show absorptions assignable to v ( C ~ 0at) 1690 cm-' and v(C=O) at 1630 cm-', where the v(C=O) of the D M F ligand is ca. 30 cm-I lower than that of free DMF. The molybdenum carbonyl complex with a strong u donor, Mo(PMe3)(C0)5, shows v(C=O) bands at 2071, 1952, and 1943 cm-',I4 while the analogous complex containing DMF, Mo(DMF)(CO)s, exhibits v(C=O) bands at 2068, 1924, and 1847 cm-I.l5 CottonI5 attributed this lower shift of v(C=O) bands in the latter complex to the r-donor capacity of DMF, which can be understood by considering the bonding in terms of the hybridization of the canonical forms, as shown here. The

'H

' H

exceedingly low v ( C ~ 0 band ) of the complex M o ( C 0 ) (DMF)(dpe)z described here may be, therefore, due to both

4450

Journal of the American Chemical Society

1

100:14

1 July 5,1978

Figure 3. Perspective view of Mo(CO)(N2)(dpe)?.l/&H6. The shapes of the atoms in this drawing represent 50%0 probability contours of thermal motions. Figure 1. Perspective view of Mo(CO)(dpe)z. The shapes of the atoms in this drawing represent 50% probability contours of thermal motions.

c1

a benzene solution of 2 changes rapidly to dark brown. From this solution, an unsaturated complex 1 is isolated as black crystals. The infrared spectrum of 1 exhibits a band a t 1807 cm-’ assignable to v ( C E 0 ) . This reaction is reversible and, dissolved in benzene under dinitrogen, 1 is easily reconverted to 2.

2

trans-Mo~CO)(Nz)(dpe)2 Mo(CO)(dpej2 2 N2 1

Figure 2. Perspective view of Mo(CO)(dpe)z. The shapes of the atoms in this drawing represent 50% probability contours of thermal motions.

the strong a-donor property of dpe ligands and the strong r-donor property of the D M F ligand.16 This complex can be recrystallized from benzene under an argon atmosphere, but is completely converted to 2 on recrystallization under dinitrogen.

3

Mo(CO)(DMF) ( d ~ e ) ~ trans- Mo(CO)(N2) (dpe)2 DMF 2 On the other hand, 2 can be directly obtained from the reaction of 3 with benzyl propionate in toluene a t reflux under dinitrogen. In this reaction, ethylene, ethane, and benzene are detected as decarbonylated products.’’ The infrared spectrum of 2 shows medium bands a t 2110 and 2080 cm-l, which change position to 2036 and 2009 cm-l upon I5N substitution and are therefore associated with v(N==N), and strong bands a t 18 12 and 1789 cm-l assignable to v ( C ~ 0 )The . splitting of u ( N r N j and v ( C ~ 0is)due to a crystal effect since such splitting was not observed in solution (v(C@) 1799 cm-l and u ( N r N ) 2128 cm-l in benzene). A sharp singlet observed at -69 ppm (relative to 85% H3P04) in the 3 1 PNMR spectrum indicates a trans configuration of 2. The dinitrogen ligand of 2 is very labile in solution, which is consistent with the high v ( NEN) caused by the presence of a strong n-acceptor CO ligand in the trans position. Thus, on removing dinitrogen in vacuo or with a stream of argon, the original orange color of

Structures of Mo(COXdpe)2 (1) and Mo(CO)(N~)(dpe)y */2C6H6(2).The structure of 1 consists of discrete, well-separated monomers. A perspective view of the complex, showing the numbering scheme, is shown in Figures 1 and 2. The carbon ring atoms are labeled as C(xyz), x being the first ring index [( 1)-(4)], y the second index [(1)-(2)], and z the position of the atom [(1)-(6)]. The carbon C ( x y z ) attaches P(x). The hydrogen atom of phenyl group H(xyz) bonds to C(xyz), and the methylene hydrogen atom H(xy) bonds to C(x). This five-coordinate complex has a nearly square-pyramidal structure with four phosphorus atoms as a basal plane and a linear carbonyl ligand in the axial position. The minimum angle between thevector from Mo to C(5) and the four phosphorus atoms’ least-squares planei8 is 87.4’ and it may be regarded as perpendicular. The structure of the complex 1 is not unexpected, because substantial evidence has been presented that five-coordinate group 6 metal(0) carbonyls and their derivatives exhibit square-pyramidal rather than trigonal bipyramidal geometry.4b9c9S,19Furthermore the predominant square-pyramidal intermediates of SNI processes have been shown to contain the best n-accepting ligand in the axial p o s i t i ~ n .As ~ ~expected, -~~ the complex 1 has an axial carbonyl ligand, which is compatible with the finding that the reaction of 1 with carbon monoxide results in the formation of trans-Mo(CO)z(dpe)2, followed by isomerization to the thermodynamically more stable cis isomer.20 The molybdenum atom of the five-coordinate complex 1 is displaced 0.13 8, out of the least-squares plane18 defined by the four coordinated phosphorus atoms toward the carbon atom of the carbonyl ligand, indicating that the molybdenum atom and the four phosphorus atoms lie nearly in the same plane. This is consistent with Hoffmann’s prediction2) that the conformation of a n MLS molecule, if it is a square pyramid, will clearly depend upon the number of the d electrons and d6 systems will favor a “flat” square pyramid. In the case of another d6 square-pyramidal complex, R u C I ~ ( P P ~ the ~)~,~~

Hidai et al.

/ Mo(CO) (N2J(Ph 2PCH2CH2PPh 2) 2-'/2C,jHg

445 1

Table V. Selected Distances (A) and Angles (deg)

MO-C( 5) Mo-N(I) Mo-P( 1 ) Mo-P(2) MO-P(3) MO-P(4) C(5)-0 N(l)-N(2) P( I)-C( I ) P( 1)-C( 1 I I ) P( 1)-C( 121) P(2)-C(2) P(2)-C(211) P(2)-C(22 I ) P(3)-C(3) P(3)-C(311) P(3)-c(32 1) P(4)-C(4) P(4)-C(411) P(4)-C(421) C-C (phenyl) C-H (phenyl) nonbonded distance Mo-H( 1 12)

Bond Distances 1.903 (9) 2.438 (2) 2.448 (2) 2.453 (2) 2.468 (2) 1.192 (12) 1.871 (8) 1.865 (9) 1.851 (8) 1.891 (8) 1.864 (8) 1.866 (8) 1.865 (9) 1.846 (8) 1.849 (9) 1.892 (9) 1.856 (7) 1.867 (8) av I .394 (25) av 0.97 (I 0)

1.973 (16) 2.068 ( 1 2) 2.459 (4) 2.447 (4) 2.435 (4) 2.452 (4) 1.127 (20) 1.087 (18) 1.852 (17) 1.847 (14) 1.805 (1 4) 1.840 ( 1 6) 1.829 (18) 1.825 ( 1 6) 1.829 (16) 1.817 (17) 1.831 (15) 1.845 ( 1 7) 1.842 ( 1 5) 1.854 (16) av 1.377 (32) av 1.01 ( 1 I )

Figure 4. Perspective view of M o ( C O ) ( N * ) ( ~ ~ ~ ) ~ . IThe / ~ Cshapes ~H~. of the atoms in this drawing represent 50% probability contours of thermal motions.

Any other significant intra- and intermolecular contacts are not observed. The maximum and minimum C-C bond distances are 1.450 (19) and 1.347 (21) A, respectively, while the C--H bond distances are 1.18 (1 1) and 0.77 ( I 1) A, respectively. We conclude that the complex 1 has a five-coordinate, 16-electron molybdenum atom, and therefore can readily combine with gaseous dinitrogen of other two-electron donating species to form six-coordinate 18-electron systems. The reversibility of the dinitrogen coordination is probably due to the tendency of the ortho hydrogen of one of the dpe phenyl groups to block this unused octahedral site, as well as the nitrogen ligand being weakly bound. Various substrates other than dinitrogen such as amines, pyridines, olefins, and amides react with 1 to yield complexes of the type trans-Mo(C0)L(dpe)2. In these reactions, the bulkiness of the substrate has a large effect in its reactivity toward l.3-22 The structure of 2 also consists of discrete, well-separated monomer and solvent molecules. A perspective view of the complex, showing the numbering scheme, is shown in Figures 3 and 4. The carbon and hydrogen atoms are named in the same way. This six-coordinate complex has octahedral geometry, with four phosphorus atoms as a basal plane and dinitrogen and carbonyl ligands in the trans axial positions. There are no significant intra- and intermolecular contacts. The maximum and minimum C-C bond distances are 1.428 (26) and 1.264 (50) A, respectively, while the C-H bond distances are 1.44 (22) and 0.83 (20) A, respectively. The solvent molecule exists near the C 2 axis, but we cannot refine the position of the molecule because of its disorder. There is a high electron density sphere ( 1 .O-2.2 e/A3) (radius ca. 1.7 A) at the center

2.98 ( 1 1) Bond Angles

C(S)-Mo-N( 1) C(5)-Mo-P( I ) C ( 5)-Mo-P( 2) C(5)-Mo-P(3) C(5)-Mo-P(4) N ( I)-Mo-P( 1) N ( 1 )- Mo-P( 2) N ( 1)- Mo-P(3) N ( I)-Mo-P(4) P( I)-Mo-P(2) P( 3)-Mo-P(4) P( I)-MO-P(3) P( 2)-Mo-P(4) P( I)-MO-P(4) P( 2)-Mo-P( 3) Mo-C( 5)-O Mo-N( I)-N(2)

90.36 (27) 92.15 (27) 95.05 (27) 95.04 (27)

79.81 (7) 79.75 (7) 174.60 (7) 172.81 (7) 99.83 (7) 99.92 (7) 178.6 (8)

174.61 (59) 85.05 (48) 87.30 (48) 100.37 (48) 90.16 (48) 90.78 (36) 95.29 (36) 84.07 (36) 87.64 (36) 79.29 (1 3) 79.48 ( 1 3) 172.89 (14) 174.60 ( 1 4) 105.26 ( 1 3) 96.28 ( 1 3) 175.0 (14) 177.0 ( 1 2)

displacement from the basal plane is 0.456 A, which may be ascribed to the bulkiness of the axial phosphine ligand. In the complex 1, the nearest hydrogen, H( 112), is 2.95 (1 1 ) A from molybdenum, suggesting van der Waals contact of the ortho hydrogen of one of the dpe phenyl groups with the metal. Table VI. Distances and IR Spectra of Carbonyl Ligands

distances, -

complexe

v(C=O), cm-1

MdCO)(dpe)2" 1807 M O ( C O ) ( N ~ ) ( ~ P ~ ) ~ . ~ / ~ C ~ H ~ "1812 1791 Mo(C0)3(cot)' I887 I734 2020 Mo(C0)4(d~m)~ 1919 1907 1881 Mo(C0)3( trien) 1898 1758

Mo-C

c-0

1.903 (9) 1.973 ( 1 6)

1.192 (12) 1.127 (20)

*

1.99 ( I )

*

*

1.93 ( I )

* 1.18 (2)

1.15 ( I )

* 2.05 (3)

*

* 1.943 (6)

* 1.152 (9)

1.12 ( I )

Carbonyls trans to the C=C Carbonyls trans to the phosphorus atoms Two mutually trans carbonyls Carbonyls trans to the nitrogen atoms

This work. J. S. McKechnie and I. C. Paul, J . Am. Chem. Soc., 88,5927 (1966); S. Winstein, H. D. Kaesz, C. G. Kreter, and E. C. Friedrich, ibid., 87, 3267 (1965). K. K. Cheung, T. F. Lai, and K. S. Mok, J . Chem. Soc. A , 1644 (1971); J. Chatt and H. R. Watson, J . Chem. Soc., 4980 (1961). F. A. Cotton and R. M. Wing, Inorg. Chem., 4,314 (1965); ref 15. e dpe = Ph*PCH*CH*PPh?;cot = cyclooctatetraene; dprn = PhzPCH2PPh2; trien = diethylenetriamine. f *, average value.

4452

Journal of the American Chemical Society

1 100:14 /

J u l y 5, I978

(x = '/z, y = 0.16, z = l/4), but there are not suitable peaks for Supplementary Material Available: Tables IIIb and IVb, positional parameters for the hydrogen atoms of Mo(CO)(dpe)z and Mo(C0)carbon atoms. (N2)(dpe)2.'&H6, respectively, and the table of observed and calSelected bond distances and angles are shown in Table V. culated structure amplitudes (18 pages). Ordering information is given The average Mo-P distances of 2.452 (2) and 2.448 (4) 8, on any current masthead page. found in the complexes 1 and 2, respectively, are nearly equal to that of 2.454 ( 1 ) 8, found in the complex 3,23but shorter than that of 2.541 (4) 8, found in [ M O F ( N Z H ~ ) ( ~ ~ ~ ) ~References ] [ B F ~ and ]~~ Notes and 2.559 ( 5 ) 8, in M0Br*(C0)3(dpe).~~ The average P-Mo-P (1) Part 5: M. Hidai, Y. Mizobe, and Y. Uchida, J. Am. Chem. SOC.,98, 7824 angles of 79.79 (7) and 79.39 (13)' found in the complexes 1 (1976). (2) (a) University of Tokyo; (b) Science University of Tokyo. and 2, respectively, are essentially equal to those found in the (3) T. Tatsumi. H. Tominaga, M. Hidai, and Y. Uchida, J. Organomet. Chem., other three complexes. Transition metal-phosphorus bonds 114, C27 (1976). are usually considered to have some double bond character (4) See, e.g., (a) W. D. Covey and T. L. Brown, lnorg. Chem., 12, 2620 (1973); (b) D. J. Darensbourg and H. H. Nelson, Ill, J. Am. Chem. SOC.,96, 651 1 presumably through back-donation (dr-d*r) from the metal, (1974); (c) D. J. Darensbourg, G. R. Dobson, and A. Moradi-Araghi, J. Orwhich greatly depends upon the electron density of the metal. ganomet. Chem., 116, C17 (1976). (5) See, e.g., (a) R. N. Perutz and J. J. Turner, J. Am. Chem. SOC.,97, 4791 The shorter average Mo-P distances of the molybdenum ze(1975);(b) J. K. Burdett. R. N. Per&, M. Poiiakoff, and J. J. Turner, J. Chem. rovalent complexes 1 and 2 compared with those of high-valent SOC.,Chem. Commun., 157 (1975); (c) J. D. Black and P. S . Braterman. molybdenum complexes reflect the greater back-donation from J. Organomet. Chem., 63, C19 (1973); (d) J. Am. Chem. SOC.,97, 2908 (1975). the metal to phosphorus ligands, which results in the shortening (6) (a) J. L. la Placa and J. A. Ibers. Inorg. Chem., 4, 778 (1965); (b) A. C. of the metal-phosphorus distances. Skapski and P. G. H. Troughton, Chem. Commun., 1230 (1968); (c) P. G. H. Troughton and A. C. Skapski, ibid., 575 (1968); (d) C. Masters, W. S. The Mo-C(5) distance of 1.903 (9) A found in the complex McDonald, G. Raper, and B. L. Show, ibid., 210 (1971); (e) K. W. Muir and 1 is one of the shortest Mo-C distances and the C - 0 distance J . A. ibers, Inorg. Chem., 9, 440 (1970). of 1.192 (1 2) 8, is one of the longest C - 0 distances, as shown (7) An apparently five-coordinate complex M ~ ( c ~ H ~ ) ( dhas p e )been ~ reported: T. Ito, T. Kokubo, T. Yamamoto, A. Yamarnoto, and S.Ikeda, J. Chem. SOC., in Table VI. On the other hand, the complex 2, which has diDalton Trans. 1783 (1974). Osborn et al., however, formulated the complex nitrogen in the trans position of the carbonyl ligands, shows as M O ( C ~ H , ) , ( ~ ~J. ~ )W. ~ : Byrne, H. U. Blaser, and J. A. Osborn, J. Am. Chem. SOC.,97, 3871 (1975). the longer Mo-C distance of 1.973 (16) 8, and the shorter C - 0 (8) (a) M. Hidai, K. Tominari, and Y. Uchida, J. Am. Chem. Soc., 94, 110 (1972); distance of 1.127 (20) 8,. (b) M. Hidai, K. Tominari, Y. Uchida. and A. Misono, lnorg. Synth., 15, 25 Goldberg and Raymond applied the "constrained model" (1974). This compound is more easily obtained in a pure state from the reaction (9) to the polycarbonyl tungsten complex, W(CO)5of Mo(CO)(N2)(dpe)2with DMF. (O=PPh2CHPPh3),26 in which they assumed a constant C - 0 (10) J. Chatt and H. R. Watson, J. Chem. SOC.,4980 (1961). (1 1) The UNICS program system for the HITAC 8700/6800 computers was distance since four equatorial carbonyl ligands are chemically employed at Tokyo University Computer Centre: Sakurai's RSLC-3 lattice equivalent. However, their constrained model could not be constants program; Ueda's PAMI Patterson and minimum function program; applied in this work, since both complexes 1 and 2 are monoIwasaki's ANSFR-P Fourier synthesis program: Ashida's HBLS-4 block-diagonal least-square and Fourier program; Ashida's DAPH distance, angle, carbonyl complexes. Insofar as this work, the differences of best plane, etc., program; and Jonson's ORTEP thermal ellipsoid plot proC - 0 or Mo-C distances of 1 and 2 are significant. These facts gram, (12) (a) D. T. Cromer and J. T. Waber, "International Tables for X-Ray Crystalsuggest that, in the complex 1, the carbonyl ligand accepts a lography", Vol. IV, Kynoch Press, Birmingham, England, 1974, Table 2.2A; considerable back-donation from the molybdenum atom and (b) D. T. Cromer and D. Liberman, ibid., Table 2.3.1. the shorter Mo-C distance and the longer C - 0 distance are (13) A . Rusina and A. A. VlcBk, Nature (London), 206, 295 (1965). (14) R. Pioiblanc and M. Bigorgne, Bull. SOC.Chim. Fr., 1301 (1962). presumably ascribable to the absence of any ligand in the trans (15) F. A. Cotton, Inorg. Chem., 3, 702 (1964). position competing for bonding electrons. In the complex 2, (16) The coordination of DMF In the complex Mo(CO)(DMF)(dpe)zthrough the nitrogen lone pair is excluded since (1) the five-coordinate complex 1 however, the Mo-C distance becomes longer, since both dicombines only with small primary and secondary amines to give Mo(C0)nitrogen and carbonyl ligands have to compete for bonding (amine)(dpe)2and it does not combine with tertiary amines such as NMe3 and (2) other bulky formamides such as HCONEt2and HCONPhZalso give electrons. analogous complexes. These results will be described in detail in a following The Mo-N-N linkage in the complex 2 is essentially linear paper. and the Mo-N distance and the N - N distance are 2.068 ( 1 2) (17) The mechanism of carbon monoxide abstraction with 3 from amides and esters will be discussed in a following paper. and 1.087 (1 8) A, respectively. The C-Mo-N linkage is also (18) Equation of the piane is 0.3579X + 0.0001 Y - 0 . 9 3 3 8 2 + 2,1829 = 0, nearly linear and the N-Mo-P angles are within the range of where the coefficients of X, Y, Zare equal to the direction cosines with 84.1 (4)-95.3 (4)'. The N-N distance of the complex 2 is respect to the axes a, b, c ' . The deviations (A) are P(1) -0.019, P(2) 0.020, P(3) -0.020, P(4)0.020, and Mo 0.135, respectively. All atoms except the shorter by 0.038 8, than the N - N distance of the complex 3,23 molybdenum atom were given unit weight in the calculation of the leastand the Mo-N distance is longer by 0.054 8, than that of the squares plane, and the molybdenum atom was given zero weight. (19) J. K. Burdett, Inorg. Chem., 14, 375 (1975). complex 3. Since the carbonyl ligand is a much stronger r (20) L. K. Holden, A. H. Mawby, D. C. Smith, and R. Whyman, J. Organomet. acceptor compared with the dinitrogen ligand, the backChem., 55, 343 (1973). donation from the molybdenum atom to the dinitrogen ligand (21) A. R. Rossi and R. Hoffmann, lnorg. Chem., 14, 365 (1975). (22) This wili be separately reported in a following paper. in the complex 2 does not occur as much as in the complex 3, (23) T. Uchida, Y. Uchida, M. Hidai, and T. Kodama, Acta Crystallogr.. Sect. 8, which is substantiated by the Mo-N and N-N distances ob31, 1197 (1975). (24) M. Hidai. M. Sato, M. Harakawa, T. Kodama, and Y. Uchida, Inorg. Chem., served and the higher v ( N r N ) at 21 10 and 2080 cm-' of the 15, 2694 (1976). complex 2 compared with v(N=N) a t 2020 and 1970 cm-I (25) M. G. 8. Drew, J. Chem. SOC.,Dalton Trans., 1329 (1972). of the complex 3.8 (26) S. Z. Goldberg and K. N. Raymond, lnorg. Chem., 12, 2923 (1973).