Daesung Chong

[Re(η5-C5H5)(CO)3]+ Family of 17-Electron Compounds : Monomer/Dimer Equilibria and Other Reactions

The anodic electrochemical oxidations of ReCp(CO)3 (1, Cp = eta(5)-C5H5), Re(eta(5)-C5H4NH2)(CO)3 (2), and ReCp*(CO)3 (3, Cp* = eta(5)-C5Me5), have been studied in CH2Cl2 containing [NBu4][TFAB] (TFAB = [B(C6F5)4]-) as supporting electrolyte. One-electron oxidations were observed with E(1/2) = 1.16, 0.79, and 0.91 V vs ferrocene for 1-3, respectively. In each case, rapid dimerization of the radical cation gave the dimer dication, [Re2Cp(gamma)2(CO)6]2+ (where Cp(gamma) represents a generic cyclopentadienyl ligand), which may be itself reduced cathodically back to the original 18-electron neutral complex ReCp(gamma)(CO)3. DFT calculations show that the SOMO of 1+ is highly Re-based and hybridized to point away from the metal, thereby facilitating the dimerization process and other reactions of the Re(II) center. The dimers, isolated in all three cases, have long metal-metal bonds that are unsupported by bridging ligands, the bond lengths being calculated as 3.229 A for [Re2Cp2(CO)6]2+ (1(2)2+) and measured as 3.1097 A for [Re2(C5H4NH2)2(CO)6]2+ (2(2)2+) by X-ray crystallography on [Re2(C5H4NH2)2(CO)6][TFAB]2. The monomer/dimer equilibrium constants are between K(dim) = 10(5) M(-1) and 10(7) M(-1) for these systems, so that partial dissociation of the dimers gives a modest amount of the corresponding monomer that is free to undergo radical cation reactions. The radical 1+ slowly abstracts a chlorine atom from dichloromethane to give the 18-electron complex [ReCp(CO)3Cl]+ as a side product. The radical cation 1+ acts as a powerful one-electron oxidant capable of effectively driving outer-sphere electron-transfer reactions with reagents having potentials of up to 0.9 V vs ferrocene.

Cycloaddition Reactions of Unactivated Olefins Catalyzed by an Organorhenium Electron-Transfer Mediator

An electrochemical process is described for the rapid and efficient conversion of unsubstituted cyclic olefins into cycloaddition products. When a potential of 1.25 V vs ferrocene was applied to a solution of cis-cyclooctene (COE) in dichloromethane/[NBu(4)][B(C(6)F(5))(4)] containing a catalytic amount (4 mol %) of ReCp(CO)(3), 1, the olefin was converted to a diastereomeric mixture of the C(8)-dimer tricyclohexadecane, with the major isomer having a cis-anti-cis geometry. Smaller cyclic olefins (C(5) to C(7)) also formed cycloaddition products. The cyclization reactions require the electrogeneration of 1(+) as an electron-transfer mediator which triggers the one-electron oxidation of the olefin in spite of the fact that the potentials of the latter lie at considerably higher values. The very low coulomb count required (ca. 0.1 F per olefin) for the conversion of olefin to product is consistent with a radical-chain mechanism. The electrochemical conversion of COE to cyclized products is complete in a few minutes, in contrast to the week-long photochemical processes previously needed for preparation of the same cycloaddition products.