Electronic structures and spectra of nitrido complexes of osmium(VI

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Volume 15

Inorganic Chemistry

Number 8 August 1976

I

0 Copyright 1976 by the American Chemical Society

Contribution No. 5265 from the Arthur Amos Noyes Laboratory of Chemical Physics, California Institute of Technology, Pasadena, California 91 125

Electronic Structures and Spectra of Nitrido Complexes of Osmium(V1) C. D. COWMAN, W. C. TROGLER, K. R. MANN, C. K. POON, and HARRY B. GRAY* Received February 3, 1976

AIC60079Q

The complexes [(n-Bu)dN][OSNX~],[(n-Pr)dN][OsNX4], and [(n-Pr)dN][OsN&(OH2)] (X- = C1-, Br-) have been prepared and characterized. Infrared spectral data suggest that the OsNX4- units in all six complexes possess CdUsymmetry. The [(n-Bu)4N] [OSNCI~]complex exhibits relatively weak electronic absorption spectral bands at 20 300 ( e 93), 22 700 ( e 77), and 25 600 cm-1 (t 50) in dichloromethane solution at 298 K. Low-temperature (77 and 5 K) spectral measurements on solid samples show that the lowest band system consists of two components. Both components are perpendicularly polarized and exhibit similar vibrational structure (al(Os=N), -800-cm-1 spacing). Assignment of the components to transitions to a Jahn-Teller split E(3E) excited state is proposed. It is estimated that the O s s N bond is lengthened by about 0.09 8,in the E(3E) state. Measurements on a single crystal at 5 K show that the band centered at 22 8 10 cm-I is parallel polarized A1(3Az)is suggested. and exhibits a 390-cm-1 progression attributable to al(Os-Cl). Assignment of this band to 'A1 The band that peaks at 25 490 cm-1 in the 5-K crystal spectrum appears to be only vibronically allowed and is attributed to 'AI Az(IA2). A progression in quanta of about 410 cm-l is observed on 'A1 Az(IA2) at low temperature. Additional bands are observed at 5 K and are assigned as follows: 30 340 cm-1 (al(Os=N) progression, -840 cm-l), 'A1 E(3B~); E(IE). The estimated Os=N bond lengthening in E(3B2) 34710 cm-l (al(Os=N) progression, -1000 cm-I), 'A1 is 0.17 A, which is consistent with a large degree of axial u-antibonding character in that excited state. A spin-orbit crystal field calculation of the d-orbital energy levels of C4,, OsNCl4- has been performed. Satisfactory agreement with the band positions in the spectrum was obtained for the following parameter values: Al(bl-bz) = 26000 cm-l; Az(e-bz) = 36000 cm-l; A3(al-bz) = 49000 cm-l; F2 = 1400 cm-l; F4 = 55 cm-l. The unusually high energies of the a1 and e levels are taken to indicate that both the u and T bonds in the 0 s ~ unit N of OsNCl4- are very strong. The electronic spectra of crystals containing related tetrahalonitrido complexes of osmium(V1) have also been measured at 5 K. The spectral features in each case are similar to those of OsNC14-, and analogous assignments have been made.

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Introduction Nitrido (N3-) complexes of transition metal ions have attracted considerable attention in recent years.' Although the M r N unit is formally analogous to M=O of the wellstudied oxo cation it is not known to what extent electronic structural parallels between the two can be drawn. For this reason, we have undertaken a detailed electronic spectroscopic investigation of a series of tetrahalonitrido complexes of osmium(V1). In this paper we report the preparation, characterization, and electronic spectra of [(n-Bu)4N] [OSNX~],[(n-Pr)4N][ O S N X ~ ]and , [(n-Pr)4N] [OsNX4(0H2)] (X- = C1-, Br-). Griffith and Pawson have independently prepared the fivecoordinate complexes O S N X ~ - , ~and ~ * the structure of [ P h d s ] [OsNC14] has been determined? In the present work, single-crystal polarized electronic spectra of several key compounds have been measured at 5 K.l0 Interpretation of the spectra has been aided by a spin-orbit crystal field calculation of OsNCL-. Experimental Section

Dropwise addition with stirring of a concentrated aqueous solution of [(n-Bu)4N]CI to the cooled solution immediately precipitated the pink [(n-Bu)4N] [OsNC14] product. The compound was filtered off, was washed with boiling dilute hydrochloric acid and then with water, and was dried in a vacuum oven at 80 OC for 6 h; yield 1.4 g, 70%. The [(n-Pr)dN] [OsNXd] complexes were obtained by dehydrating the corresponding [(n-Pr)dN][OsNX4(0Hz)] compounds in a vacuum oven at 78 O C for 5 h. [(n-Bu)4N][OsNC14]was recrystallized from dichloromethane-hexane and dichloromethane-chloroform solutions. Large square crystalline plates of the compound were grown. The other compounds were recrystallized from acetonitrile solution. Analytical data for these compounds are given in Table I. Physical Measurements. Electronic spectral data were obtained using a Cary 17 spectrophotometerequipped with an Andonian liquid helium Dewar and double Glan Taylor air-spaced calcite polarizers. For the low-temperature spectroscopic studies, crystals were grown on aluminum oxide and quartz substrates. Crystals of [(nBu)4N] [OsNC14] are tetragonal, space group P4/n,with lattice parameters a = b = 11.757 (l), c = 8.789 (1) The osmiumnitrogen bond line coincides with the crystallographic fourfold axis. As crystals formed on the (001) face, only perpendicular (or a) polarized spectra were obtained.

Results and Discussion Infrared spectral similarities suggest12 that the OsNX4- and OsNX4(0H2)- units all possess C4" symmetry, by analogy to the geometrical structure of O s N C L found in crystalline c o m p o ~ n d s . ~ J ~In~ the ' ~ ground state, the Os=N bond distance is extremely short, being 1.60 A in [Ph&][OsNC14]? Under the assumption of a strong axial ligand field, the d orbitals are expected to increase in energy according to b2 (dxy)

Preparation of Compounds. K[OsO3N] was prepared by a standard method." [(n-Bu)lN] [OsNX4] and [(n-Pr)4N] [OsNX4(0H2)] (X= C1-, Br-) were prepared by adding the appropriate tetraalkylammonium halide to an HX solution of K[OsO3N]. Details are given for [(n-Bu)4N] [OSNCI~]. K[OsO3N] (1.0 g, 0.0034 mol) was dissolved in hydrochloric acid (8 ml, 4 M). The solution, which immediately turned red, was placed on a steam bath for 5 min. The solution was then diluted by addition of an equal volume of water.

1747

Gray et al.

1748 Inorganic Chemistry, Vol. 15, No. 8, 1976 Table I. Analytical Data for Tetrahalonitrido Complexes of Osmium(V1) % calcd Complexes

H

C

[(n-Bu),N] [OsNCl,] [(n-Pr),N] [OsNCl,] [ (E-Pr) qN1 [OsNCl, (OH, 11 [(n-Bu),N] [OsNBr, 1 [ (n-PI) ,N] [OsNBr ] [(n-Pr),Nl [OsNBr,(OH,)l

32.6 27.1 26.2 25.1 20.3 19.8

6.16 5.30 5.49 4.74 3.97 4.15

Table 11. Ligand Field Transitions in C,, OsNC1,One-electron Excited Oneelectron transition state transition

% found

N

X

C

H

N

X

4.75 5.26 5.09 3.66 3.95 3.85

24.1 26.6 25.8 41.7 45.0 43.9

32.5 27.2 26.4 25.1 20.4 20.0

6.20 5.33 5.35 4.73 4.02 3.99

4.69 5.12 4.97 3.64 3.97 3.87

24.2 26.8 26.0 41.3 44.8 43.7

a

Excited state

4%

I*

a

Ground state is ' A , (bZz). I

t l

1

I

I 400

m

nm

EC?

52:

-

I

Figure 3. Electronic absorption spectrum of a single crystal of [(n-Pr),N][OsNCl,(OH,)] at 5 K.

I

1

500

600

Figure 1. Electronic absorption spectra of a Nujol mull of [(~-Bu),N][OSNC~,]:A, 77 K;B, 298 K.

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Figure 2. Electronic absorption spectrum measured on the (001) face of a single crystal of [(n-Bu),N][OsNCl,] at 5 K.

< e (d,,, dyz) bl (dxz-yz) < a1 (d9). The ground state for d2 OsNX4- is therefore lA1(b2~).The e and a1 orbitals possess nitrogen-osmium T - and a-antibonding character, respectively. Table I1 gives the symmetries of the ligand field excited states for transitions from b2 to the e, b1, and a1 orbitals. Spin-orbit coupling is included, as it is expected to be of considerable importance in an Os(V1) complex. In C4" symmetry, transitions from a 'A1 ground state to A1 and E excited states are allowed. The electronic absorption spectrum of [(n-Bu)4N] [OsNC14] in dichloromethane solution at 298 K shows distinct bands centered at 20 300 (E 93), 22 700 (E 7 7 ) , and 25 600 cm-' (E 50). Additionally, shoulders are observed at 18 300 and 28 000 cm-l. Intense absorption occurs at energies greater than 33 000 cm-1. The relatively low intensities of the bands below 33 000 cm-l suggest that many of them may arise from transitions to excited states derived from spin triplets. In a solid sample of [(n-Bu)4N] [OsNC14] at low temperature, the lowest energy shoulder is resolved at 18 120 cm-' (Figure 1). The band at 20410 cm-l sharpens and vibrational fine structure with a spacing of 750-860 cm-' is observed. We shall refer to the 20 410-cm-' maximum and its low-energy shoulder as band system I. An analogous system is observed in [(n-Bu)4N] [OsNBrd]. Peak positions in system I taken from 5-K measurements on single crystals of [(n-Bu)4N][OsNC14] and [(n-Bu)4N] [OsNBr4] are given in Table 111. The fact that band system I is observed in the axial (001) spectrum of [(n-Bu)4N] [OsNC14] at 5 K clearly demonstrates that it is perpendicularly polarized (Figure 2). The lower energy component is slightly red-shifted and therefore more

pronounced in the 5-K spectrum of [(n-Pr)4N] [OsNC14(0H2)] (Figure 3). Moreover, sharper vibrational structure is detected in the axially aquated compound. The main vibrational progression of 800-900 cm-' is attributed to the excited-state al(Os=N) stretching mode (ground state -1 120 cm-I).l2 The fact that a reduction of the Os=N stretching frequency is observed indicates an increase in that bond distance in the excited state. As the Poisson formula14 may be fit with a Franck-Condon factor of 1.68 for band I in [(n-Pr)4N][OsNC14(0H2)], we estimate that the Os=N bond lengthening is approximately 0.09 A (taking 9.67 rndynlh; for the stretching force constant).15 The progression in al (Os=N) is split by 162 cm-' in [(n-Pr)dN] [OsNC14(0H2)] (Figure 3) and by 119 cm-' in [(n-Pr)4N][OsNBr4(OH2)] (Table IV). From the dependence on halide, assignment of this low-frequency mode to an al(OsX4) umbrella deformation is proposed. For comparison, the analogous ground-state deformations in [PhdAs] [OsNC14] and [Ph4As] [OsNBr4] occur15 at 184 and 122 cm-', respectively. It is unlikely that the lowest a-polarized band is 'A1 E(3A2) (Le., b2 bl), as the E(3A2) excited state has cr* character with respect to the halide ligands. Such cr* character is inconsistent with the relative insensitivity of the position of band system I to halide substitution and also with the fact that a progression in al(0s-X) is not present. We conclude, therefore, that band system I results from the one-electron excitation b2 e. Population of an antibonding e orbital effectively reduces the O s N bond order and is consistent with a lower stretching frequency (and bond lengthening) in the excited state. Assuming band system I is derived from b2 e, it remains to assign the excited states associated with the two components. The two components could be attributable either to 'Ai E(3E) split by Jahn-Teller vibronic interactions or to the two

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Inorganic Chemistry, Vol. 15, No. 8, 1976 1749

Nitrido Complexes of Osmium(V1)

Table 111. Electronic Absorption Spectra of Tetrahalonitrido Complexes of Osmium(V1) at 5 K [ (n-Bu) N ] [0sNBr ]

[(~-Bu),N][OSNCI,] nma

cm- '

I

527.0 549.5 591.3 482.4 463.2

18 200 15)000 19 950 20 730 21 590

I1

446.0 443.7 438.4 435.9 431.2 428.8 424.1 421.9 414.9 406.5 399.7 392.3 386.4 381.0 358.9 349.0 339.4 329.6 320.3 312.7 304.5

22 420 22 540 22 810 22 940 23 190 23 320 23 58b 23 700 24 100 24 600 25 020 25 490 25 880 26 250 27 860 28 650 29 460 30 340 31 220 31 980 32 840

296.9 288.1 280.0

33 680 34 710 35 710

Band

I11

IV

V

Spacing

]in 800

nma

cm-

575.3 546.5 508.0 486.9 466.2 444.7

17 380 18 300 19 690 20 540 21 450 22 490

'A,

]920

N3E)

-+

1040 A,('A,)

390]120

1

Spacing

b

38OIl4O 3 9 0 7 30 ~ 320

7400

j;; 860

416.2

24 030

390.2 388.1 382.1 378.5 373.8 364.1 35 8 .I 355.8 347.0 337.3 328.1 322.1 316.4

25 63OC 25 770 26 170 26 420 26 750 27 460 27 880 28 100 28 810 29 650 30 480 31 050 31 600

a Uncertainties in peak positions are generally k1.0 nm. A band attributable to ' A , --t A1('A2)was observed at 2 1 325 cm-' in dichloromethane solution. A complex series of peaks begins here. It is likely that transitions to E(3B2)and E('E) overlap in this region.

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transitions 'A1 E('E) and 'A1 E(3E).16 Complete spin-orbit crystal field calculations show that the latter interpretation is untenable (vide infra). Therefore, we conclude that band system I is attributable to split components of the transition 'A1 E(3E>. Spectral data for the higher energy band systems in [(nBu)4N] [OsNX4] and [(n-Pr)4N] [OsNX4(0H2)] complexes are set out in Tables I11 and IV, respectively. Band 11, which is centered at 22810 cm-' in [(n-Bu)4N] [OsNC14] at 5 K, is not observed in perpendicular polarization. The parallel polarization of this band suggests that it be assigned to 'A1 A1(3E) or to 'A1 A I ( ~ A ~The ) . fact that band I1 shifts over 1400 cm-' to the red in the spectrum of OsNBr4-supports the latter choice, as the A I ( ~ A excited ~) state*isantibonding with respect to the equatorial ligands. The doubled vibrational progression of 390 cm-' split by 130 cm-' for [(n-Bu)4N][OsNC14] indicates an excited-state distortion in al(Os-Cl), which is additional evidence in favor of the one-electron b2 bl origin of A I ( ~ A ~The ) . corresponding a1 metal-halide stretching frequency in the ground state has been reported15 to be 358 cm-'. The 130-cm-' splitting observed at 5 K could result from coupling of the a r deformation (ground state 184 cm-l)15 to the a1 stretch. Thus band I1 may be assigned confidently to the transition 'A1 A1(3A2). The weak band that peaks at 25490 cm-l (111) in [(nBu)4N] [OsNC14] at 5 K is perpendicularly polarized. This band is assigned to the orbitally forbidden transition 'A1 A2( lA2), which, in the Herzberg-Teller coupling scheme,17 is vibronically allowed only in perpendicular polarization. Band 111is red-shifted in the bromide complexes, as was found for band 11. Band I11 also slightly blue-shifts upon cooling,

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-

consistent with a vibronic intensity-giving mechanism. Vibrational structure with a spacing of about 410 cm-' is assigned to an excited-state deformation in al(Os-Cl), as expected for a one-electron excitation to the bl orbital. Note that 'Ai E(3A2) is not observed, presumably because it is weak and obscured by band system I. The next feature in the 5-K spectrum of [(n-Bu)4N][OsNCL] is a broad, perpendicularly polarized band (IV) with a maximum at 30 340 cm-l. A long progression with a spacing of about 840 cm-' is observed, and standard analysis14 gives a Franck-Condon factor of 6 or greater. Taking an Os=N stretchihg force constant of 9.67 mdyn/A,15 as before, we estimate an Os=N bond lengthening of about 0.17 A in the excited state in question. Assignment of band IV to 'A1 E(3B2J is consistent with such large 0-N bond lengthening, as substantial axial u* character is predicted for the E(3B2) excited state. Band IV is not found in the same region in the spectrum of [(n-Pr)4N] [OsNC14(0H2)] (Figure 3), and we assume it falls at higher energy. In [(n-Bu)4N] [OsNBr4], a complex system of overlapping bands begins a t 25 630 cm-l. It is likely that transitions to E(3B2) and E('E) occur in this region, but we are not able to make any specific peak assignments at this time. Band IV in the 5-K spectrum of [(n-Pr)4N] [OsNBr4] appears less complex, being comprised of a -750-cm-' progression beginning at 26 830 cm-'. A relatively intense, perpendicularly polarized progression (V) in quanta of about 1000 cm-' originates at 33 680 cm-' in tlie spectrum of [(n-Bu)4N][OsNC14] at 5 K. Band V, which does not appreciably shift upon axial H 2 0 coordination, is assigned to 'A1 E('E). As noted above, transitions to E( 'E) in the bromide complexes are not well separated from

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1750 Inorganic Chemistry, Vol. 15, No. 8,1976

Gray et al.

Table IV. Electronic Absorption Spectra of Tetrahalonitridoaquo Complexes of Osmium(V1) at 5 K [ (n-Pr) 4Nl[OsNBr ,(OH d 1

[ (n-Pr),Nl [OsNCl, (OH,) 1

Band I

I1

111 IV

V

.ma 617.8 611.7 605.7 599.7 593.8 588.2 585.2 579.6 574.1 568.8 563.5 558.4 555.9 550.8 545.9 541.2 536.5 530.0 525.6 521.2 516.8 507.1 502.9 498.9 495.1 491.4 486.2

cm16 190 16 350 16 510 16 680 16 810 17 000 17 090 17 250 17 420 17 580 17 750 17 910 17 990 18 160 18 320 18 480 18 640 18 870 19 030 19 190 19 350 19 720 19 880 20 040 20 200 20 350 20 570

463.5 460.4 455.4 452.4 449.6 447 .I 444.8 44 1.9 440.5 437.5 434.8 430.2 398.0

21 570 21 720 21 960 22 100 22 240 22 340 22 480 22 630 22 700 22 860 23 000 23 250 25 100

344.4 355.3 363.6

34 440 35 530 36 360

-

Spacing

900 170 -

8 80

850

850

-150

390

nmn 626.6 62 1.9 616.9 612.4 607.9 603.5 599.2 592.8 588.6 584.5 580.4 576.4 572.4 568.5 562.7 559.0 555.6 551.9 548.2 544.7 541.4 538.5 535.3 532.8 526.6 523.3 520.0 516.5 513.3 510.2 507.1 507.6 504.5 501.8 498.5 495.5 492.6 485.0 48 1.9 479.2 476.2 411.5 47 1.O

cm- I 15 960 16 080 16 210 16 330 16 450 16 570 16 690 16 870 16 990 17 110 17 230 1 7 350 17 470 17 590 17 770 17 890 18 000 18 120 18 240 18 380 18 470 18 570 18 680 18 770 18 990 19 110 19 230 19 360 19 480 19 000 19 720 19 700 19 820 19 930 20 060 20 180 20 300 20 620 20 750 20 870 21 000 21 120 21 230

427.4 372.7 361.5 350.8 342.2 333.9 326.5

23 400 26 830 27 660 28 510 29 220 29 950 30 630

Spacing

'A,

+

120

120 120 120 120 120 120 900 120 110 120 120 120 110 100 110 120 120 120 130 120 120 120 30

380 380

+2 (145)

380 380 390 360 380 370 390 -

Uncertainties in peak positions are generally i1.0 nm.

those attributable to 'AI E(3B2). Our assignments for the five-band systems were based in part on a spin-orbit crystal field calculation of the energy levels of OsNC14-. Matrix elements for all single excitations in OsNCL- were expressed in t e r m of a spin-orbit parameter a = f/2, the three crystal field splittings AI = E(b1) - E(b2), A2 = E(e) - E(b2), and A3 = E(a1) - E(b2), and the Sla-

ter-Condon parameters, F2 and F q . I 8 In the calculation, CY was fixed at 1000 cm-l, which accords with the value of 950 cm-' found19 for the (tzs)(eg) configuration of OsF6. Various combinations of AI, A2, A,, F2, and F4 were employed in the crystal field calculations. Satisfactory agreement with the spectral data for OsNC14- was achieved for A I = 26000, A2 = 36000, A3 = 49000, F2 = 1400, and F4 = 55 cm-I (Table

Inorganic Chemistry, Vol. 15, No. 8, I976 1751

Raman Studies of Bas3

observations made previously.26 Acknowledgment. We thank Richard Kahn for assistance with the ligand field calculations and Professor Robert Bau for helpful comments. This research was supported by the National Science Foundation.

Table V. Calculated and Observed Electronic Transitions in OsNC1,-

-

..

‘A, --* W3E) A, A, (3Az) Az(’Az) E(3B,) WE) a

v,,(oFsd), cm-

v,,(calcd), cm-’

19 300a b b 22 810 25 490 30 340 34 710

Average position of the two components.

19 596 20 395 21 360 22 149 25 246 29 544 32 615

Registry No. [(n-Bu)4N][OsNC14], 42993-50-0; [(n-Pr)4N][OsNC14], 59219-46-4; [(n-Pr)lN][OsNC14(0Hz)], 59187-87-0; [(n-Bu)dN] [OsNBro], 42720-45-6; [(n-PrkN] [OsNBu], 59 187-88-1; [(n-Pr)4N] [OsNBy(OH2)], 591 87-90-5; K[OsO3N], 21774-03-8. Supplementary Material Available: Crystal field matrices with inclusion of spin-orbit coupling and sample calculations (2 pages). Ordering information is given on any current masthead page.

* Not observed.

V). More precise fitting would be meaningless in view of the crudeness of the theory. It is somewhat reassuring that the assigned values of parameters F2, F4, and Ai for OsNC14- are in good agreement with those obtainedz0 from a detailed analysis of the electronic spectrum of PtC1d2- (Fz = 1406, F4 = 54, A1 = 25 961 cm-l). Such close correspondence is to be bond expected, as the Os-Cl(2.31 & l o and Pt-Cl (2.32 distances are nearly equal. It should be pointed out that in all of our computations,18 even when the values of F2 and F4 were greatly reduced, the 1E-3E splitting was found to be greater than 6000 cm-’. This is the main basis of our assignment of both components of band system I to transitions to a split E(3E) state. It is not likely that the higher component is ‘A1 E(lE), as in that case the implied singlet-triplet splitting would be well below the lower limit set by theory. The unusually high energies of the osmium d orbitals (e, al) that interact with the nitrido group are particularly noteworthy. Indeed, the antibonding character of the e level in Os=N appears to be much greater than that inferred for M=O from spectral studies of oxo cation complexes containing second- and third-row metal~.22>~~ We take this result to mean that nitride is a much better a donor than is oxide, a conclusion not incompatible with recent Mossbauer spectral experiments on R u ( V I ) ~ and ~ O S ( V I ) nitrido ~~ complexes that clearly indicate the presence of a high degree of ligand metal electron donation. It should also be emphasized that our analysis suggests that both u and a nitridmsmium bonds are very strong. As electron donation from N3- to a metal center increases, the nucleophilic character of the coordinated nitrido group decreases. Our electronic structural model for O s r N , then, would suggest a rather low nucleophilicity for the nitrido ligand, which accords well with experimental

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References and Notes (1) (2) (3) (4)

W. P. Griffth, Coord. Chem. Rev., 8,369 (1972), and references therein. C. J. Ballhausen and H. B. Gray, Inorg. Chem., 1, 111 (1962). R. A. Wentworth and T. S. Piper, J . Chem. Phys., 41, 3884 (1964). C. J. Ballhausen,B. F. Diurinskii, and K. J. Watson, J . Am. Chem. Soc.,

90, 3305 (1968). ( 5 ) J. Selbin, Coord. Chem. Rev., 1, 293 (1966). (6) W. P. Griffith. Coord. Chem. Rev.. 5. 459 (1970). (7) W. P. Griffith and D. Pawson, J . Chem. Soc., Chem. Commun., 418

(1973).

(8) W. P. Griffith and D. Pawson, J. Chem. Soc., Dalton Tram., 1315 (1973). (9) S.R. Fletcher, W. P. Griffith, D. Pawson, F. L. Phillips,and A. C. Skapski, Inorg. Nucl. Chem. Lett., 9,1117 (1973); F. L. Phillips and A. C. Skapski, J . Cryst. Mol. Struct., 5, 83 (1975). (10) A preliminary report of the spectra of Kz[OsNC15] and [(n-Bu)4N][OsNC14] has been published: C. K. Poon and H. B. Gray, Proc. XII Int. Conf. Coord. Chem., 12, 26 (1969). (11) A. F. Clifford and C. S. Kobayashi, Inorg. Synth., 6, 204 (1960). (12) 0. Siiman and C. K. Poon, unpublished results; C. D. Cowman, Ph.D. Thesis, California Institute of Technology, 1974. (13) J. Chiang, M.S. Thesis, University of Southern California, 1974 (R. Bau,

private communication).

(14) E. I. Solomon and C. J. Ballhausen, Mol. Phys., 29, 279 (1975). (15) R. J. Collin, W. P. Griffith, and D. Pawson, J . Mol. Struct., 19, 531

(1973).

(16) The band splitting cannot be a result of a low-symmetry Os site, as the anion in a crystal of [(n-Bu)rN][OsNC14] is rigorously C4u.12.13 (17) G. Herzberg, “Molecular Spectra and Molecular Structure”, Vol. 111, Van Nostrand-Reinhold, Princeton, N.J., 1966, p 140. (18) Supplementary material. (19) W. Moffitt, G. L. Goodman, M. Fred, and B. Weinstock, Mol. Phys., 2, 109 (1959); J. C. Eisenstein, J . Chem. Phys., 34, 310 (1961). (20) H. H. Patterson, J. J. Godfrey, and S.M. Kahn, Inorg. Chem., 11,2872 (1972). H. J. M. Bowen, Chem. SOC.,Spec. Publ., No. 11 (1958). H. B. Gray and C. R. Hare, Inorg. Chem., 1, 363 (1962). E. A. Allen, B. J. Brisdon, D. A. Edwards, G. W. A. Fowles, and R. G. Williams, J . Chem. Soc., 4649 (1963). (24) T. C . Gibb, R. Greatrex, N. N. Greenwood, and R. H. Meinhold, Chem. Phys. Lett., 29, 379 (1974). (25) F. E. Wagner, D. Kucheida, U. Zahn, and G. Kaindl, Z . Phys., 266, 223 (1974). (26) J. Chatt and J. R. Dilworth, J . Chem. SOC.,Chem. Commun., 508 (1974).

Contribution from Cogswell Laboratory, Rensselaer Polytechnic Institute, Troy, New York 12181

Raman Studies of Sulfur-Containing Anions in Inorganic Polysulfides. Barium Trisulfide G. J. JANZ,’ E. RODUNER,’ J. W. COUTTS,2 and J. R. DOWNEY, Jr.

AIC60027 1 Received January 9, 1976 The present work reports an investigation of the S32- anion from -125 to 580 OC using laser-Raman and rotating scattering arrangements as principal techniques, with Bas3 (mp 554 “C) as the model system. The room-temperature and low-temperature spectra are understood in terms of a Ca symmetry for S32-. A unique spectral transformation occurs at higher temperature and in addition the compound exhibits a temperature-independent but magnetic-field-dependent paramagnetism. These changes are discussed from the viewpoint of bond angle changes, resonance Raman effect, and rotation of the S3*-species in the solid state.

Introduction The alkali and alkaline earth metals form a series of POlysulfides containing Sn2- anions. Since complex equilibria undoubtedly occur between species such as S2- and Sn2-,we have undertaken the characterization of some of the Sn2-

anions using, as model systems, a series of inorganic polysulfides for which the structures have been well characterized by careful x-ray crystallographic studies. The present work reports the results of an investigation of the S32- anion using laser-Raman spectroscopy as the principal technique and, as