The Mechanism of Isomerization of Olefins with ... - ACS Publications

Abstract: A mechanism is proposed for the isomerization of olefins with compounds of ... be described as the reduction of proton to hydridewith concur...
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3534

The Mechanism of Isomerization of Olefins with Transition Metal Catalysts Richard Cramer and R. V. Lindsey, Jr.

Contribution No. 1184 from the Central Research Department, Experimental Station, E. I. du Pont de Nemours and Company, Wilmington, Delaware 19898. Received March 3, 1966 Abstract: A mechanism is proposed for the isomerization of olefins with compounds of rhodium, palladium, platinum, nickel, or iron as catalysts and with a variety of cocatalysts. A kinetically stable metal hydride with coordinated substrate olefin rearranges first to a metal alkyl, then to the metal hydride complex of the isomeric olefin. Initial hydride formation may occur by various routes depending upon the cocatalyst and the oxidation state of the metal. However, isomerization generally proceeds (and hydride is regenerated) by a reversible reaction which may be described as the reduction of proton to hydride with concurrent two-electron oxidation of the metal.

D

ouble-bond migration, particularly in linear, terminal olefins, is catalyzed by solutions of coordination compounds of many transition metals. Frequently a cocatalyst is required; hydrogen,' acids, and oxygenated organic compounds3 have been used for this purpose. We recently encountered isomerization in the hydrogenation of olefins with platinum-tin chloride complexes as catalysts4 and in the dimerization of ethylene with rhodium(1) compounds and HCl.5 The latter system was examined more closely, and it was found that isomerization of I-butene in CH,OD solution led to displacement of approximately one olefin proton by deuterium for each molecule of I-butene that was isomerized. Surprisingly, the product contained substantial amounts of deuterated I-butene and nondeuterated 2 - b ~ t e n e s . ~In order to account for these results a variant of the hydride addition-elimination mechanism (eq 1) was proposed which incorporated a moderately stable olefin-rhodium(II1) hydride. Examination of other transition metal catalysts and other mH

+ RCH2CH=CH2 -+ RCHzCHCH3

[

]

----f

RCH=CHCH3 f m H

(1)

cocatalysts has been undertaken to evaluate the mechanism more extensively. Results Compounds of rhodium(1 and 111), platinum(II), palladium(II), nickel(O), and iron( - 11) were employed as catalysts. Recurrent characteristics of these reaction systems are that: (1) a cocatalyst is generally required ; (2) regardless of the cocatalyst, isomerization is facilitated by acid; (3) isomerization in deuterated solvent yields deuterated olefin. (1) (a) G. C. Bond and M. Hellier, Chem. Ind. (London), 35 (1965); (b) R. D. Gillard, J. A. Osborn, P. B. Stockwell, and G. Wilkinson, Proc. Chem. Soc., 284 (1964). (2) (a) M. Feller, H. M. Brennan, and H. S. Seelig, U. S. Patent 2,960,550 (Nov 15, 1960); (b) J. Milgrom and W. H. Urry, Abstracts, Proceedings of the Seventh International Conference on Coordination Chemistry, Stockholm, Sweden, 1962, p 264. (3) (a) T. A. Manue1,J. Org. Chem., 27, 3941 (1962); (b) J. F. Harrod and A. J. Chalk, J . Am. Chem. SOC.,86, 1776 (1964). (4) R. Cramer, E. L. Jenner, R. V. Lindsey, Jr., and U. G. Stolberg, ibid., 85, 1691 (1963); cy. ref la. (5) R. Cramer, J . Am. Chem. SOC.,87, 4717 (1965). (6) R. Cramer, ibid., 88, 2272 (1966).

Journal of the American Chemical Society

88:15

Rhodium-Catalyzed Isomerization. A. HCl Cocatalyst. The ((C2H4)2RhCl)2-HClcatalyzed isomerization of butenes has been described in detaiL6 Although solutions of rhodium(1) complexes in methanolic HC1 appear to be much more efficient catalysts than rhodium(II1) chloride in ethanol,3b the two systems are potentially equivalent. Rhodium(II1) chloride can be reduced by olefin' or ethanols to rhodium(1) and, in fact, this may be essential to catalyst activity. If the rhodium trichloride-ethanol catalyst is first heated with 1-butene at 60", the resulting solution, when freed of butene isomers and contacted with fresh I-butene, was effective at O", and its activity was further increased by addition of HCl. Chloride appears to be an essential component of the catalyst. There is no detectable isomerization of 1-butene in 5 hr at 0" by a solution of bis(ethylene)rhodium(I) acetylacetonate (acacRh(C2H4)2)in 1 Methanolic sulfuric acid. B. Hydrogen Cocatalyst. It has been reported'b that 1-hexene isomerizes during its hydrogenation at 20" in the presence of rhodium trichloride. We found that rhodium(II1) chloride with hydrogen as cocatalyst isomerized 1-butene more slowly than catalyst derived from acacRh(CzH& or ((CzH4)2RhC1)2 and HCl, possibly because less rhodium is converted to a catalytically active form rather than intrinsic inferiority. (Uncertainty concerning catalyst concentration applies to most of the systems described here.) No isomerization was observed with rhodium(II1) perchlorate and hydrogen. Hydrogen will also activate a rhodium(1) compound provided that chloride (or, possibly, other halide) is present. Thus, hydrogen with acacRh(C2H& dissolved in 0.5 M methanolic lithium chloride isomerized 1-butene completely within 16 hr at 25," but there was no observable reaction in the absence of lithium chloride. Rhodium(1) chloride-stannous chloride complexes$ and hydrogen also catalyze olefin isomerization. As the Sn/Rh ratio is increased, isomerization is slower, and at 6 : 1 virtually stops. Isomerization in CH3OD solution yields deuterated butenes. The isomerization/ deuteration ratio is much larger when SnCh is included with either HC1 or Hz as cocatalyst (Table I). A base (lithium acetate, magnesium oxide, sodium bicarbonate) reduces the rate of rhodium-catalyzed

1 August 5, 1966

(7) R. Cramer, Inorg. Chem., 1, 722 (1962). (8) J. Chatt and L. M. Venanzi, J . Chem. SOC.,4735 (1957). (9) J. F. Young, R. D. Gillard, and G. Wilkinson, ibid., 5176 (1964).

3535 Table I.

Composition of Butenes from Rhodium-Catalyzed Isomerization-Deuteration of 1-Butene"

Exvt

Reactants. mmole

1

((GH4)2RhC1)2,0.13 nc1,1

2

((CzH&RhCl)?, 0.13 SnCh 2H20,0.25 DC, 1 RhC13.3Hz0,0.25 HP,0.25

3 4

5

RhCI3.3Hz0,0.25 SnClz.2Hz0, 0.50 Hz, 0.25 RhC13 3Hz0,O. 25 SnCh 2Hz0, 0.75 HP,0.25

CaHs,

Butene, 'Z 1-Butene, 59.9 trans-2-Butene, 21.2 cis-2-Butene, 18.9 1-Butene, 33.4 trans-2-Butene, 21.3 cis-2-Butene, 45.3 1-Butene, 72.4 truns-2-Butene, 13.7 cis-2-Butene, 13.9 1-Butene, 38.9 trans-2-Butene, 35.1 cis-2-Butene, 26.0 1-Butene, 65.0 trans-2-Butene, 16.0 cis-ZButene, 19.0

a All experiments at 0" with 2 ml of C H 3 0 D and 8 mmoles of 1-butene. butenes.

isomerization to less than one-tenth the uninhibited rate regardless of the cocatalyst. Isomerization was not detected when I-butene was stirred with a methanolic solution of (pyrRhC12)C1and NaBH4 (mole ratio 1 : 1) for 24 hr at 0". These reactants are reportedlo to give a rhodium hydride. Platinum-Catalyzed Isomerizations. A. Ethanol Cocatalyst. The ((CzH4)PtC12)z-ethanol catalyst described by Harrod and Chalk3bhas an induction period, and we find that isomerization is faster if the catalyst mixture is preheated for about 1 hr before exposure to olefin. Even so, the catalyst is significantly active only above about 50". B. Acid Cocatalyst. I-Butene isomerized at a moderate rate at 25" (60% of 8 mmoles in 23 hr) in contact with 0.06 mmole of H2PtCI6, 0.31 mmole of SnCI2, and 0.1 ml of CF3COOH. Both H2PtC16 and SnC12are essential. C. Hydrogen Cocatalyst. Isomerization of I-pentene by platinum-tin chloride complex and hydrogen has been reported,l" and catalysis has been ascribed to a platinum hydride. We found isomerization to be slow in acetone or water but much faster in methanol where the rate exceeded that of CF3COOH-cocatalyzed reactions. Isomerization of 1-butene in C H 3 0 D with H2PtCleSnC12-H2 (see Table 11) resembles the rhodium-catalyzed reaction. Thus, the product contained much deuterated 1-butene and nondeuterated 2-butenes, also the deuteration/isomerization ratio was about the same at 0" as at -24". However, in the rhodium-catalyzed reaction, isomerization exceeds deuterium exchange while with platinum there is more deuteration than isomerization. Also the ratio of cis- and trans-2butene is significantly different. An equilibrated mixture of linear butenes contains about 22 % cis-2-butene and 75 % trans-2-butene at 25 ". Isomerization with rhodium gives an excess of cis-2-butene; frequently the cisltrans ratio is greater than one. But the platinum catalyst produced more trans-2-butene (cf. Bond and Hellier'"). cis- and trans-2-butenes were isomerized with HzPtC16SnC12-H2 in C H 3 0 H at 25 The ratios of the amounts

".

(10) R. D. Gillard and G. Wilkinson, J. Chem. Soc., 3594 (1963).

Cramer, Lindsey

z

CaHiD,

CaHsDz,

%

%

77 71 63 80 80 81 86 82 86 92 90 90

21 25 32 19 17 16 13 16 12 7 9 9

99

1

Isom/ Deut ratio

2 4

1.3

5

1 2 2 1 2 2 1 1 1

3 1.9

6

0.2

35

* Mass spectroscopic analysis on unfractionated

mixture of

Table 11. Isomerization-Deuteration of 1-Butene with HZptCls-SnCl2-Hz in CH,OD

A. n-Butane (8.3 %) 1-Butene (71.9 %) cis-2-Butene (4.5 %) rrans-2-Butene (15.2%) B. n-Butane (2.0 %) 1-Butene (66.4%) cis-2-Butene (8.8 %) trans-2-Butene (22.8 %)

17 Hr at - 2 4 " ~ 72 27 55 40 53 41 7.5 Hr at OD*

1 5 6

64

1 7 7

35 38 39

54 54