Fluorine-19 nuclear magnetic resonance spectrum of the

R. G. Kidd, and R. W. Matthews. Inorg. Chem. , 1972, 11 (5), pp 1156–1157. DOI: 10.1021/ic50111a058. Publication Date: May 1972. ACS Legacy Archive...
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1156 Inorganic Chemistry, Vol. 11, No. 5 , 1972

NOTES

Hatton, et al. (JF-121Sb = 1945 (is) Hz; J F - I ~ =~s~ 1055 ( * 5 ) H Z ) . ~ ,A~ value of JF-lBISb = 1820 Hz has also been determined from the 19Fnmr of solid KSbF6.’ The chemical shift of AgSbF6 in acetonitrile, ~ C F C ~ ~ f123 ppm, is within about 10 ppm of values found for absorptions previously assigned to SbF6-.”Ifl Since IgFnmr spectra previously reported for this ion have consisted of single absorptions with varying line Acknowledgment.-Appreciation is expressed to the widths, i t was of interest to determine, qualitatively a t Research Corp., Du Pont, and the donors of the least, the factors influencing resolution of the multiplet. Petroleum Research Fund, administered by the AmeriFor spin-spin coupling involving quadrupolar nuclei can Chemical Society, for partial support of this work, (I > I / * ) , the component line widths depend on the and t o Professor Gilbert Haight for helpful discussions. rate of quadrupole relaxation. Increase of either the (11) A. I. Brodskii and L. V. Sulima, Dokl. Akad. N a u k S S S R , 92, 589 electric field gradient around the high-spin nucleus or (1953); Chem. Abstr., 48, 5620d (1954). the rotational correlation time should increase the rate of relaxation and thus broaden the resonance lines.11 For ionic species, the electric field gradient is expected to be sensitive to the magnitude of ion-ion interactions COXTRIBUTION FROM THE DEPARTMENT OF CHEMISTRY, and hence to changes in dielectric constant (E) of the UNVERSITYOF WESTERSOKTARIO, solvent and change of the counterion. Previous studies LOSDON72, ONTARIO, CANADA of the lgF nmr of the hexafluoroarsenate(V)12 and -niobate(V) 13-15 ions have demonstrated the dependence of multiplet resolution on these factors. The Fluorine-19 Nuclear Magnetic Resonance We have found similar results for SbF6- in nonSpectrum of the Hexafluoroantimonate(V) Ion aqueous solution. The I9F nmr of dilute solutions of ,4gSbF6 in dimethyl sulfoxide ( 6 = 45.0) and N , N BY R. G. KIDDA N D R. W. MATTHEW*] dimethylformamide ( e = 36. 1) showed resolution comparable to that for acetonitrile solution ( E = 3 8 . 0 ) , Received September 20, 1971 but noticeable broadening of the components occurred The V i b and 123Sbnmr spectra of the octahedral for dilute solutions in acetone ( E = 20.7). The comhexafluoroantimonate(V) ion in solutions of NaSbF6 ponent line widths are also sensitive to change of cation. or SbF, in 48% aqueous hydrofluoric acid are k n ~ w n ~ - A ~ solution of NaSbF6 in acetonitrile, similar in concento consist of seven-line multiplets due to spin-spin tration to that used to determine the 19Fspectrum of coupling of I9Fwith the antimony nucleus. The corAgSbF6 (-2 M ) showed considerable broadening of responding multiplet structure expected for the I9Fnmr both IgF and IZ1Sb multiplets. Saturated solutions spectrum of this species, however, has apparently not of AgSbFe in dimethyl sulfoxide, N,N-dimethylformbeen observed. We have now obtained complete resoluamide, and acetone were highly viscous and showed tion of this spectrum using a solution of the silver(1) considerably broadened bands in their I9Fspectra, consalt in acetonitrile. The 14-line spectrum consists of a sistent with the increase in correlation time compared sextet arising from coupling of lZISb (I = 5//2) with I9F, to dilute solutions. I n the temperature range 1-50 to superimposed on an octet due to coupling of lz3Sb(I = -40”) the I9F spectra of the dilute solutions showed i/!J with I9F. The spectrum is shown in the figure tolittle change. The broad multiplets in the I9Fspectra gether with the corresponding IZ1Sb and lz3Sb nmr of the viscous solutions, however, progressively cospectra obtained in this laboratory. The coupling alesced to give somewhat sharper singlets as the temconstants determined from the 19F spectrum are perature was lowered. The various line shapes were JF-~ =~ 1934 I~ ( 4~ ~ 1 5 Hz ) and JF-lzaSb = 1047 (k.25) similar to those calculated by Suzuki, et aZ.j From Hz. The ratio J F - l ? l S b / J F - l U S b is 1.85 (*0.06), in these results, we conclude that, in nonaqueous solvents, good agreement with the ratio of the gyromagnetic multiplet resolution is mainly determined by solvent ratios 71/21/7123 = 1.8466. The relative intensities of dependence of the rate of quadrupole relaxation. any two components due respectively to coupling with Compared to their acetonitrile solutions, AgSbF6 IZ1Sband lz3Sbis approximately 2 : 1, as expected for the and NaSbF6 in 48y0 aqueous hydrofluoric acid showed isotopes in their natural abundances (IZISb, 57.2$Z0; considerable broadening of the I9Fand IZ1Sbmultiplets. lZ3Sb,42.8%). Although the symmetry of the intensity (6) T h e instrumentation used t o observe t h e antimony nmr spectra does pattern is somewhat unsatisfactory (see Experimental not allow us t o match t h e precision of the results quoted b y these authors. Section), the overall line shape of the sextet is in qualita(7) E . R. Andrew, L. F. Farnell, and T. D. Gledhill, Phys. Rea. Lett., 19, 6 (1967). tive agreement with that calculated by Suzuki and (8) J. Bacon, P. A. W.Dean, and R . J. Gillespie, C a n . J . C h e m . , 48, 3413 Kuboj for the nmr spectrum of a nucleus of spin I = (1970). coupled to a nucleus with spin I = s/2. The values (9) M. Azeem, M . Brownstein, and R. J. Gillespie, ibid., 47, 4159 (1969). (10) E. L. Muetterties and W. I). Phillips, 5. Amei. Chem. S o c . , 81, 1084 of the coupling constants are in good agreement with (1959). those obtained from lZISband lZ3Sbnmr spectra by (11) J , A. Pople, Mol. P h y s . , 1, 168 (1968). is qualitatively supported by the results of ‘80-exchange studies between water and phosphorus acids ; the firstorder rate constants for exchange” decrease with increasing phosphorus oxidation state, k (H3P02) >> k(H3P03) >> k(H3P04). We anticipate that the aciddependent aquation of the Cr(04PH2)2rion is even slower than that of Cr(03PH2)*+.

(1) Address correspondence t o this author a t t h e University Chemical Laboratory, Lensfield Road, Cambridge, CB2 l E W , England. (2) W. G. Proctor and F. C . Y u , Phys. Rev., 81, 20 (1951). (3) S. S. Dharmatti a n d H . E . Weaver, Jr.. ibid.,87, 675 (1952). (4) 3. V. Hatton, Y. Saito, and W. G . Schneider, C a n . J . Chem., 43, 47 (1965). ( 5 ) M. Suzuki and R. Kubo, M o l . Phys., 7, 201 (1964).

(12) K. J. Packer and E . L. Muetterties, P Y O CC . h e w . Soc., London, 147 (1964). (13) K. J. Packer and E . L. Muetterties, J . Amer. Chem. SOL.,86, 3035 (1963). I. and K. J. Packer, 3101. Phys., 14, (14) D. V i . Aksnes, S.&Hutchison, 301 (1968) (15) K . C. Moss, J . Chem. Soc. A , 1224 (1970).

NOTES The addition of water or 48% aqueous hydrofluoric acid to AgSbFe in acetonitrile showed similarly broadened lines. I n the absence of information concerning possible exchange processes involving fluoride ion and viscosity and dielectric constant changes in these solutions, we are unable to account for the observed multiplet broadening. Experimental Section Sample Preparation.-AgSbF6 and NaSbFe were obtained from Alfa Inorganics and used without further purification. Spectro Grade solvents were used. Solutions were normally prepared in the air although unnecessary exposure of reagents to the atmosphere was avoided. The possible effects of moisture absorbed from the atmosphere were tested by preparing a sample solution under dry nitrogen. Acetonitrile was dried by distillation from calcium hydride under nitrogen and a previously unopened sample of ilgSgF6 was recrystallized from this solvent. The l9F nmr of this solution showed no significant difference compared t o that of a similar solution prepared in the air with spectroscopic grade solvent. On exposure to light, freshly prepared solutions of AgSbFs produced a black material, presumably metallic silver, after a few minutes. This did not appear to affect the nmr spectra in any way other than t o decrease signal intensity after exposure to light for several days. Nmr Spectra.-The ISFspectra were obtained using a Varian HA-100 spectrometer operating a t 94.1 MHz. The spectrvm illustrated in Figure 1 was obtained using a modified HA field-

Inorganic Chemistry, Vol. 11, No. 5, 1972 1157 difficulty was experienced in correctly phasing the broad (100200 Hz) components in this mode. Consequently, each value was obtained from measurements on the two appropriate components with the best line shapes. The precision is a subjective estimate of the accuracy in determining the band maxima. The '2Sb and lz3Sb nmr spectra were obtained with a Varian 4200B wide-line spectrometer combined with a 9-in. magnet. I n a field of 14.1 kG, frequencies of 14.4 and 7.8 MHz were used for Ia'Sb and lZ3Sb,respectively. The spectra shown in Fgure 1 were recorded as the derivative of the absorption mode.

Acknowledgment.-We are indebted to Mrs. H. M. Schroeder for running the 19Fnmr spectra and we thank Dr. M. C. Woods for helpful discussions. Financial support of this study in the form of operating grants from the University of Western Ontario (to R. W. M.) and the National Research Council of Canada (to R. G. K.) is gratefully acknowledged.

CONTRIBUTION NO. 1867 FROM THE CENTRAL RESEARCH DEPARTMENT, E. I. DU P O N T D E NEMOURS AND COMPANY, EXP~RIMENTAL STATIOK, WILMINGTON, DELAWARE19898

Tellurates of the Type A2+Te04 BY A. W. SLEIGHT,*C. M. FORIS, AND M. S. LICIS

"F

Received October 20, 1971

Although sulfates and selenates of the A2+S04 and A2+Se04 types are well known, little is known about anhydrous A2+Te04tellurates. Only BaTeOd is well We have now prepared and characterized tellurates of this type where A is Mg, Ca, Sr, Ba, Cd, or Pb.

"'5 b

'23Sb

Figure 1-The 'SF, lz1Sb, and lz3Sbnmr spectra of the SbFeion. The spectra are shown relative to a common frequency scale. sweep mode. The lock was switched off and the manual oscillator was replaced by an external oscillator generating about 15,000 Hz. We were unable t o obtain a symmetrical intensity pattern using this mode. The coupling constants were determined by scanning each component separately in an HA frequency-sweep mode using trifluoroacetic acid to provide a lock signal Considerable

Experimental Section The reactants were reagent grade or better. The syntheses were generally carried out a t high pressure and temperature. Appropriate quantities of the reactants were intimately mixed, sealed in gold tubes, and heated a t 700' with 3000 a t m of supporting pressure for 8 hr. The reactant mixtures were of the types AClz.xHnO-hTa~TeOa.2Hz0,AO-HzTe04.2H20, or A( O H ) Z . ~ H ~ O - H Z T ~ O ~ . ~hHmixture Z O . of PbOn and TeOz could also be used to prepare PbTe04. Preparations a t 600" under 1 a t m of flowing oxygen were successful for making polycrystalline samples of BaTeO4, SrTe04, and CdTeOa. Anal. Calcd for MgTeOa: Mg, 11.3; Te, 59.1; 0, 29.6. Found: Mg, 11.5; Te, 58.7; 0, 29.4. Calcd for CdTe04: Cd, 37.0; Te, 42.0; 0 , 2 1 . 0 . Found: Cd, 36.8; Te, 42.3; 0 , 2 1 . 4 . Calcd for CaTeOa: Ca, 17.3; Te, 55.1; 0, 27.6. Found: Ca, 17.2; Te, 55.4; 0, 27.3. Calcd for SrTeOr: Sr, 31.4; Te, 45.7; 0, 22.9. Found: Sr, 31.4; Te, 45.5; 0, 22.8. Calcd for BaTe0 4 : Ba, 41.8; Te, 38.8; 0, 19.5. Found: Ba, 41.9; Te, 38.4; 0, 19.1. Calcd for PbTeO4: Pb, 52.0; Te, 32.0; 0, 16.0. Found: Pb, 52.4; Te, 29.9; 0, 16.2. X-Ray powder patterns were obtained on all products a t 25' using a Guinier-Hagg camera with Cou KLYIradiation and an internal standard of KCl (a = 6.2931 A). Single-crystal photographs were taken with a precession camera using Mo radiation. Cell dimensions were refined by least squares using the Guinier data. Thermogravimetric analyses (tga) employed a Du Pont 900 thermal analyzer and a heating rate of 10°,/min.

Results The A2+Te04tellurates where A2+is Mg, Ca, Sr, Ba, or Cd are white, and PbTe04 is light yellow. They ( 1 ) A. Engelbrecht and F. Sladky, Monalsh. Chem., 9 6 , 360 (1965). (2) R.N. Knyazeva and A. P. Kurapova, Rcss. J . Inwg. Chem., 14, 1220 (1969).