Carbon-13 nuclear magnetic resonance of organophosphorus

John H. Brownie and Michael C. Baird , Derek R. Laws and William E. Geiger .... Hubert Schmidbaur , Wolfgang Richter , Walter Wolf , Frank H. Köhler...
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discussions of this work with Dr. George C. Levy and Dr. Arnold Satterthwait. We also acknowledge partial support of this work by the Rutgers Research Council and the Biomedical Sciences Support Grant (USPH-

FR-7058) to Rutgers University, as well as support from a National Institutes of Health special fellowship (C. K. Sauers) and the hospitality of the Brandeis University Graduate Department of Biochemistry.

Carbon- 13 Nuclear Magnetic Resonance of Organophosphorus Compounds. VIII. Triphenylphosphoranes and Triphenylphosphonium Salts George A. Gray

Contribution from the Eastern Region Applications Laboratory, Varian Associates Instrument Division, Springfield, New Jersey 07081. Received M a y 30, 1973 chemical shifts and 13C-31Pnuclear spin coupling constants have been obtained for six triphenylphosphoraries (phosphorus ylides), twelve triphenylphosphonium salts, triphenylphosphine oxide, and tetraphenylphosphonium bromide. In the salts the substituted phenyl carbon shifts vary slightly while the methylene resonance parallels analogously substituted carbon shifts in the series CH3X, CHICH~X,c-CGH1lX,and (C2H50)2P(0)CH2X. The methylene carbon IJCPvaries through a range of over 30%. No correlation is found with the related ‘JCP’S in the above series. The ylides show strikingly high shieldings and one-bond 13C-31Pcouplings for the ylide carbons. These shieldings are typical for aliphatic carbon and point toward high localization of negative charge on basically sp2 carbons. Their ~ J Cvalues P are much larger than the one-bond couplings to the sp2carbons in the phenyl rings. The data indicate a delocalized cyclopentadienide phosphorane while the fluorenide phosphorane has much more localization on the ylide carbon. Abstract:

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rganophosphorus compounds continue to provide demanding tests of our understanding of their syntheses, equilibria, and molecular electronic structure. We have been using ninr as a means of probing the structures, conformation, and bonding of different kinds of these interesting compounds. l--? As opposed to the (now) typical use of 13C spectra for chemical shifts, organophosphorus compounds also exhibit both long and short range 1aC-31P nuclear spin couplings, which are especially useful in investigating stereochemistry and bonding. In part V5 considerable attention was given to the sensitivity of the 13C shifts and 13C-31Pcouplings in four-membered phosphorus heterocycles to the formal phosphorus oxidation state, particularly to the differences between P(1V) and P(V). In its higher oxidation “states,” phosphorus has often been described as being able to form multiple bonds with adjacent atoms possessing lone -pair electrons via a d v p r interaction. Thus, oxides are often written as R3P=0 (even though both lone pairs on the oxygen are usually felt to be participating in what should be viewed as a pseudotriple bond). Another class of compounds in which it is common to invoke dr-pir bonding is that of phosphorus ylides, R3P=CR ’R”. These compounds are “stabilized” by using conjugating groups for R, R’, and R”. A popular version of G. A. Gray, J.Amer. Chem. Soc.,93,2132(1971). G . A. Gray and S . E. Cremer, T e t r a h e d r o n k f f .3061 , (1971). G. A. Gray and S. E. Cremer, J. Org. Chem., 37,3456 (1972). G. A. Gray and S . E. Cremer, Chem. Commun., 367 (1972). G. A. Gray and S. E. Cremer, J . Org. Chem., 37,3470(1972). (6) G. A. Gray and S . E. Cremer, J . Mug. Resonance, in press. (7) G. A. Gray, J. Amer. Chem. SOC.,95,5092 (1973). (1)

(2) (3) (4) (5)

stabilized ylides is that of Ph3PC(R)C02R’, for which lH nmr data are available.8-10 It has been common t o interpret their stereochemistry and bonding in terms of the general valence-bond structures a-c. The elecR‘

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tronic differences within a-c should give rise to fundamental differences in the l3C shieldings and 13C-31P couplings for atoms in the ylide bond and/or those bound to them. Structure b is essentially that of a phosphonium salt and c a carbanion which could be, in principle, either trigonal or tetrahedral with formal sp2 or sp3 hybridization schemes for the ylide carbon. The dr-pir “back bonding” depicted by a presents an electronic distribution for which few data are available. We have now determined the I3C chemical shifts and lP nuclear spin couplings in a series of phosphorus ylides of the type Ph3PC(R)C02R’as well as the cyclopentadienyl- and fluorenyltriphenylphosphoranes. As examples of analogous P(1V) compounds and to explore (8) H. J. Bestmann and J. P. Snyder, ibid., 89,3936 (1967). (9) F. J. Randalland A. W. Johnson, TetruhedronLeft., 2841 (1968). (10) D. M. Crouse, A. T. Wehman, and E. E. Schweizer, Chem. Commun., 866 (1968). (11) Very recently 13C data have been reported for (CHdaP=CHn showing a dipolar ylide structure containing an sp* carbanion and an sp3 onium center, a bonding description very similar to that proposed here for the triphenylphosphoranes: H. Schmidbaur, W. Buchner, and D. Scheutzow, Chem. Ber., 106,1251 (1973).

Journal of the American Chemical Society / 95:23 1 Nor;ember 14, 1973

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IaCNmr of Organophosphorus Compounds

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