Treatment of MH(OTf)(dppm)₂ (M = Ru, Os) with CH₂=C=CHR (R = Ph, ⁿC₅H₁₁ and CO₂Et) led to the formation of allyl complexes [Ru(η³-CH₂CHCHR)(dppm)₂]OTf. Treatment of OsH(OTf)(dppe)₂ with CH₂=C=CHR led to the formation of η²-coordinated complexes [OsH(η²-CH₂=C=CHR)(dppm)₂]OTf. Reactions of MH(OTf)(PP)₂ (PP = dppm, dppe) with CH₃CH=C=CHCO₂Et gave either vinyl- or allyl products. ₃...[ Read more ]

Treatment of MH(OTf)(dppm)₂ (M = Ru, Os) with CH₂=C=CHR (R = Ph, ⁿC₅H₁₁ and CO₂Et) led to the formation of allyl complexes [Ru(η³-CH₂CHCHR)(dppm)₂]OTf. Treatment of OsH(OTf)(dppe)₂ with CH₂=C=CHR led to the formation of η²-coordinated complexes [OsH(η²-CH₂=C=CHR)(dppm)₂]OTf. Reactions of MH(OTf)(PP)₂ (PP = dppm, dppe) with CH₃CH=C=CHCO₂Et gave either vinyl- or allyl products.

The readily available and relatively cheap metal salt RuCl₃ showed high efficiency in catalyzing C-H amination reactions of C-H bond of ortho-aryl phenylazides, 1-azido-2-arylvinylazides, and 1-azido-1,3-butadienes. Both computational and experimental results support that a two-step process involving formal electrocyclization is involved in the reaction mechanism.

Treatments of metal cyclopentadienyl complexes with TlPF₆ afforded thallium bridged trimetallic complexes. The in situ NMR experiments and theoretical studies support that a [(η⁵-C₅H₅)M(TlH)(PR₃)₂]⁺ or a [(η⁵-C₅H₅)M(TlH)(PR₃)₂]₂(Tl)⁺ intermediate is involved in the reactions.

A computation study showed that many metallabenzene complexes are thermodynamically unstable with respect to the correponding Cp complexes. However, stable metallabenzenes could be obtained by using proper choice of ligands, metals and substituents on the metallabenzene rings.