226882-89-9Relevant articles and documents
Iridium and rhodium complexes containing fluorinated phenyl ligands and their transformation to η2-Benzyne complexes, including the parent benzyne complex IrCp*(PMe3)(C6H4)
Hughes, Russell P.,Laritchev, Roman B.,Williamson, Alex,Incarvito, Christopher D.,Zakharov, Lev N.,Rheingold, Arnold L.
, p. 4873 - 4885 (2008/10/08)
The iridium and rhodium complexes containing fluorinated phenyl ligands were discussed. The crystal structures of these complexes were discussed and the 'through-space' nature of some coupling constants was confirmed. The transformation of these complexes
Deprotonation of the transition metal hydride (η5-C5Me5)(PMe3)IrH2. Synthesis and chemistry of the strongly basic lithium iridate (η5-C5Me5)(PMe3)Ir(H)(Li)
Peterson, Thomas H.
, p. 2005 - 2020 (2008/10/08)
Treatment of (η5-C5Me5)(PMe3)IrH2 (1) with tert-butyllithium gives (η5-C5Me5)(PMe3)Ir-(H)(Li) (2) as a bright yellow solid. NMR evidence indicates that the lithium iridate 2 is aggregated in benzene, is converted to a single symmetrical species in THF, and is present as a dimer in DME. Treatment of 2 with 3,3-dimethylbutane trifluoromethanesulfonate-1,2-syn-d2 (3-syn-d2) gave the alkylated hydridoiridium complex 4a-anti-d2, which was converted to the corresponding chloride Cp*(PMe3)Ir(CHDCHDCMe3)(Cl) (4c-anti-dz) by treatment with CCl4. Analysis of this material by NMR spectroscopy showed that it was contaminated with ≤15% syn isomer. The alkylation therefore proceeds with predominant inversion of configuration at carbon, indicating that the major pathway is an SN2 displacement and not an outer-sphere electron-transfer reaction. Protonation studies carried out on iridate 2 with organic acids of varying pKa allowed us to estimate that the pKa of the dihydride 1 falls in the range 38-41, making it less acidic than DMSO and more acidic than toluene. This represents the least acidic transition metal hydride whose pKa has been quantitatively estimated. Treatment of 2 with main group electrophiles allowed the preparation of several other hydridoiridium derivatives, including Cp*(PMe3)Ir(SnPh3)(H) (5a), Cp*(PMe3)Ir(SnMe3)(H) (5b), and Cp*(PMe3)Ir(BR2)(H) (6a, R = F; 6b, R = Ph). Reaction of 2 with acid chlorides and anhydrides leads to acyl hydrides Cp*(PMe3)Ir(COR)(H), and fluorocarbons also react, giving products such as Cp*(PMe3)Ir(C6F5)(H) in the case of hexafluorobenzene as the electrophile.