56. "Synthesis and Structure of
Intermediates in
Copper-Catalyzed Alkylation of Diphenylphosphine." Cain, M. F.; Hughes, R. P.; Glueck, D.
S.;
Golen, J. A.; Moore, C. E.; Rheingold, A. L. Inorg. Chem. 2010, 49, 7650–7662.
Abstract
Cu(I) catalysts for alkylation of
diphenylphosphine were developed. Treatment of [Cu(NCMe)4][PF6]
(1) with chelating ligands gave
[CuL(NCMe)][PF6] (2;
L = MeC(CH2PPh2)3 (triphos), 3;
L = 9,9-dimethyl-4,5-bis(diphenylphosphino)xanthene (XantPhos)). These
complexes catalyzed the alkylation of PHPh2 with PhCH2Br in the presence of the base NaOSiMe3 to yield PPh2CH2Ph (4). The
precursors Cu(dtbp)(X) (dtbp =2,9-di-t-butylphenanthroline, X = Cl (5) or OTf (6)), CuCl, and 1 also catalyzed this reaction, but
dtbp dissociated from 5 and 6 during catalysis. Both 2 and 3 also catalyzed alkylation of PHPh2 with PhCH2Cl/NaOSiMe3, but XantPhos dissociation was observed when 3 was used. When CH2Cl2 was used as the solvent for alkylation of PhCH2Cl with precursors 2
or 3, or of PhCH(Me)Br with 2, it was competitively alkylated to
yield PPh2CH2Cl (7), which
was formed exclusively using 2
in the absence of a benzyl halide. Cu(triphos)-catalyzed alkylation of
PhCH(Me)Br gave mostly PPh2CHMePh (8),
along with some Ph2P-PPh2 (9), which
was also formed in attempted alkylation of dibromoethane with this
catalyst. The phosphine complexes [Cu(triphos)(L')][PF6] (L' = PH2Ph (10), PH2CH2Fc (Fc = C5H4FeC5H5, 11), PHPh2 (12), PHEt2 (13), PHCy2 (Cy = cyclo-C6H11, 14),
PHMe(Is) (Is = 2,4,6-(i-Pr)3C6H2, 15), PPh2CH2Ph (16), PPh2CH2Cl (17)), and
[Cu(XantPhos)(L')][PF6] (L' = PHPh2 (18), PPh2CH2Ph (19)) were
prepared by treatment of 2 and
3 with appropriate ligands.
Similarly, treatment of dtbp complexes 5
or 6 with PHPh2 gave [Cu(dtbp)(PHPh2)(X)] (X = OTf (20a)
or Cl (20b)), and reaction of
PPh2CH2Ph (4) with 1 formed [Cu(PPh2CH2Ph)3][PF6] (21). Complexes 2,
3, 11-14, 16, 17, 19, and 21 were
structurally characterized by X-ray crystallography. Deprotonation of
diphenylphosphine complex 12
in the presence of benzyl bromide gave diphenylbenzylphosphine complex 16, while deprotonation of 12 in CD2Cl2 gave 17
containing a PPh2CD2Cl ligand. Low-temperature deprotonation of the
soluble salt 12-[B(ArF)4] (ArF = 3,5-(CF3)2C6H3) in THF-d8 gave the phosphido complex Cu(triphos)(PPh2) (22).
Thermally unstable 22 was
characterized by NMR spectroscopy and, in comparison to 12, by density functional theory
(DFT) calculations, which showed it contained a polarized Cu-P bond.
The ligand substitution step required for catalytic turnover was
observed on treatment of 16 or
17 with PHPh2 to yield equilibrium mixtures containing 12 and the tertiary phosphines 4 or 7; equilibrium constants for these
reactions were 8(2) and 7(2), favoring complexation of the smaller
secondary phosphine in both cases. These observations are consistent
with a proposed mechanism for catalytic P-C bond formation involving
deprotonation of the cationic diphenylphosphine complex
[Cu(triphos)(PHPh2)][PF6] (12) by
NaOSiMe3 to yield the phosphido complex Cu(triphos)(PPh2) (22).
Nucleophilic attack on the substrate (benzyl halide or CH2Cl2) then yields the tertiary phosphine complex
[Cu(triphos)(PPh2CH2X)][PF6] (X = Ph (16)
or Cl (17)), and ligand
substitution with PHPh2 regenerates 12.