Theoretical investigation of the stability, equilibrium geometry, and electronic structure of the (CH3)2SiH+and+CH2CH3SiH2cations

## Abstract The multiple‐channel reactions SiH~3~ + SiH~3~CH~3~ → products and SiH~3~ + SiH~2~(CH~3~)~2~ → products are investigated by direct dynamics method. The minimum energy path (MEP) is calculated at the MP2/6‐31+G(d,p) level, and energetic information is further refined by the MC‐QCISD meth

## Abstract Raman spectra of 1,3‐disilabutane (SiH~3~CH~2~SiH~2~CH~3~) as a liquid were recorded at 293 K and as a solid at 78 K. In the Raman cryostat at 78 K an amorphous phase was first formed, giving a spectrum similar to that of the liquid. After annealing to 120 K, the sample crystallized and

The structures ofcthylidcne and propylidene in their lowest singlet states :ue considered using INDO lnd MIND 112 calculations. Using a gadicnt optimization method, it is found that R!INDO/Z predicts no encrg minimu.n f-or singlet ethylidenc, while INDO predicts non-&ssic4 bridged structures for the

It is concluded that C3H80+' formed by dissociation of ionized 2ethoxyethanol ( ) is a mixture of CH,CH,OCHl' (7) and 'GH,+OHCH,CH, (2). Formation of 7 and CH3CH2+0HCH3 ( ) is attributed to dissociations of species formed by the hydrogen transfers [ CH,CH20CH2+ 'CH,OHI + [CH,CH,OCHi' CH,Ol -+ [CH,CH