Summary: The isomerization of the branched 2M3BN to the linear 3PN by a DPEphosNi species has been investigated by means of variable-temperature NMR spectroscopy, and activation parameters have been determined. An intermediate in this reaction, which is formed via C-C bond activation, could be trapped by addition of ZnCl 2 , and the molecular structure of the corresponding Ni(II) complex has been determined by X-ray crystallography.Among C-C bond formation reactions, the hydrocyanation of alkenes is an attractive, yet challenging, route for the functionalization of carbon-carbon double bonds. 1,2 The isomerization of 2-methyl-3-butenenitrile (2M3BN) to 3-pentenenitrile (3PN), for example, is closely related to hydrocyanation and is at the same time an important step in the industrial adiponitrile process. 3 In combination with Ni(cod) 2 , all classes of bidentate phosphorus ligands (phosphines, 4,5 phosphinites, 6 phosphonites, 4,7 and phosphites 8 ) catalyze the isomerization, without the addition of Lewis acids. However, the influence of ligand parameters on this conversion still remains unknown. The isomerization is, in fact, a suitable reaction to study reductive elimination to the final product 3PN without the deactivation of the catalyst usually caused by HCN during hydrocyanations. 9,10 We started a spectroscopic investigation of the isomerization of 2M3BN to 3PN catalyzed by DPEphos/ Ni(cod) 2 to study the reductive elimination of nitriles, which is the crucial step in catalytic hydrocyanation reactions. In fact, we were moved to report on our results because of recent contributions in this field by Santini et al. 11 and Chaudret et al. 5 Upon addition of 1 equiv of DPEphos to Ni(cod) 2 in toluene-d 8 the 31 P NMR spectrum displays a singlet at δ 33.1 ppm for the species (DPEphos)Ni 0 (cod) (1) (Scheme 1). This signal disappears on addition of approximately 3 equiv of 2M3BN at -35°C, and two doublets appear at δ 21.3 and 24.2 ppm, with 2 J PP ) 38 Hz. These resonances correspond to (DPEphos)Ni 0 -(2M3BN) (2), with 2M3BN coordinating most likely through its alkene bond; the η 2 -alkene complex (DPEphos)Ni 0 (styrene) gives a very similar 31 P NMR spectrum, which shows two doublets at δ 20.2 and 22.9 ppm with 2 J PP ) 44 Hz. When the temperature is raised to +25°C, the two doublets of 2 disappear and a signal could no longer be detected in the 31 P NMR spectrum.The 1 H NMR spectrum shows broad signals at δ 4.5 (CHCH 2 ), 3.4 (CHCH 3 ), 2.4 (1H, CH syn H anti ), 1.6 (CH 3 ), and 1.2 (1H, CH syn H anti ) ppm. Increasing the temperature to +35°C causes slow isomerization of 2M3BN to 3PN, indicated by the methyl signals in the 1 H NMR spectrum. The 3PN analogue (DPEphos)Ni 0 (3PN) (5) could not be detected with VT NMR spectroscopy when approximately 5 equiv of 3PN was added to 1. However, 1 disappears and the same broad signals in the 1 H NMR spectrum occur which were detected upon warming of 2. We ascribe this spectrum to (DPEphos)Ni II (C 4 H 7 )(CN) (3), which is formed by oxidative addition of 2M3BN or
