Organotin Compounds

“…Photolysis with a Zn resonance lamp (214 nm) of a deoxygenated 0.02 M solution of 4b in cyclohexane- d 12 containing 0.5 M methanol (MeOH), with periodic monitoring of the photolyzate by (600 MHz) 1 H NMR spectroscopy, resulted in the formation of 2,3-dimethyl-1,3-butadiene (DMB) and a colorless precipitate that deposited on the walls of the NMR tube. A collection of very weak peaks was also present in the 0.5−0.8 ppm range of the spectrum (including a singlet at δ 0.53 ppm), consistent with (SnMe 2 ) n oligomers, but no new signals were detectable in the δ 3.5−5.5 ppm region, where those due to Sn−H and Sn−OMe protons would be expected …”

“…The magnitude of this barrier could explain why the methoxystannane is in fact not formed in detectable amounts in steady-state trapping experiments (vide supra); the ultimate fate of SnMe 2 in the latter experiments, even in the presence of relatively high concentrations of alcohol, is oligomerization. Few examples of stable alkoxydialkylhydridostannanes are known, ,, but water and MeOH are known to undergo oxidative addition to Lappert's stannylene {Sn[CH(SiMe 3 ) 2 ] 2 } to afford the corresponding (stable) O−H insertion products . The reaction was proposed to proceed via initial formation of the corresponding stannylene−alcohol (water) complex, but if this complex can rearrange readily to product, then the required H migration must either have a lower barrier than that calculated by Su for the SnMe 2 −MeOH complex ( 6 ) 40 or proceed catalytically.…”

Direct Detection of Dimethylstannylene and Tetramethyldistannene in Solution and the Gas Phase by Laser Flash Photolysis of 1,1-Dimethylstannacyclopent-3-enes

“…Photolysis with a Zn resonance lamp (214 nm) of a deoxygenated 0.02 M solution of 4b in cyclohexane- d 12 containing 0.5 M methanol (MeOH), with periodic monitoring of the photolyzate by (600 MHz) 1 H NMR spectroscopy, resulted in the formation of 2,3-dimethyl-1,3-butadiene (DMB) and a colorless precipitate that deposited on the walls of the NMR tube. A collection of very weak peaks was also present in the 0.5−0.8 ppm range of the spectrum (including a singlet at δ 0.53 ppm), consistent with (SnMe 2 ) n oligomers, but no new signals were detectable in the δ 3.5−5.5 ppm region, where those due to Sn−H and Sn−OMe protons would be expected …”

“…The magnitude of this barrier could explain why the methoxystannane is in fact not formed in detectable amounts in steady-state trapping experiments (vide supra); the ultimate fate of SnMe 2 in the latter experiments, even in the presence of relatively high concentrations of alcohol, is oligomerization. Few examples of stable alkoxydialkylhydridostannanes are known, ,, but water and MeOH are known to undergo oxidative addition to Lappert's stannylene {Sn[CH(SiMe 3 ) 2 ] 2 } to afford the corresponding (stable) O−H insertion products . The reaction was proposed to proceed via initial formation of the corresponding stannylene−alcohol (water) complex, but if this complex can rearrange readily to product, then the required H migration must either have a lower barrier than that calculated by Su for the SnMe 2 −MeOH complex ( 6 ) 40 or proceed catalytically.…”

Direct Detection of Dimethylstannylene and Tetramethyldistannene in Solution and the Gas Phase by Laser Flash Photolysis of 1,1-Dimethylstannacyclopent-3-enes

A novel and convenient method for trifluoromethylation of organic halides using CF3SiR'3/KF/Cu(I) system