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Tri-n-butylsilyl radical, also known as (n-Bu3Si)?, is a chemical species characterized by a silicon atom bonded to three n-butyl groups and an unpaired electron. This radical is a member of the silyl radicals family, which are known for their unique reactivity and stability. The tri-n-butylsilyl radical is of interest in various chemical reactions, particularly in the field of organosilicon chemistry, where it can act as a reducing agent or a ligand in transition metal complexes. Its stability is attributed to the hyperconjugation effect, where the unpaired electron is delocalized over the three n-butyl groups, reducing the radical's reactivity. This radical has potential applications in the synthesis of organosilicon compounds and as a probe for studying radical reactions.

60604-28-6

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60604-28-6 Usage

Check Digit Verification of cas no

The CAS Registry Mumber 60604-28-6 includes 8 digits separated into 3 groups by hyphens. The first part of the number,starting from the left, has 5 digits, 6,0,6,0 and 4 respectively; the second part has 2 digits, 2 and 8 respectively.
Calculate Digit Verification of CAS Registry Number 60604-28:
(7*6)+(6*0)+(5*6)+(4*0)+(3*4)+(2*2)+(1*8)=96
96 % 10 = 6
So 60604-28-6 is a valid CAS Registry Number.

60604-28-6Downstream Products

60604-28-6Relevant academic research and scientific papers

Kinetics of hydride transfer reactions from hydrosilanes to carbenium ions. Substituent effects in silicenium ions

Mayr, Herbert,Basso, Nib,Hagen, Gisela

, p. 3060 - 3066 (2007/10/02)

Rates of hydride transfer from hydrosilanes HSiR1R2R3 with widely varying substitution to para-substituted diarylcarbenium ions have been measured in dichloromethane solution. Generally the reactions follow a second-order rate law, -d[Ar2CH+]/dt = k2[Ar2CH+][HSiR1R2R3], and k2 is independent of the degree of ion-pairing and the nature of the counterion (exceptions are reported). The reaction rates are almost independent of solvent polarity. Kinetic isotope effects exclude an SET-type mechanism and are in accord with a polar mechanism with rate-determining formation of silicenium ions. The reactivities of para-substituted aryldimethylsilanes are linearly correlated with σp (ρ = -2.46), not with σp+. In the series H3SiHex, H2SiHex2, HSiHex3, the relative reactivities are 1.00:155:7890, and in the corresponding phenyl series the reactivity increase is much smaller (H3SiPh:H2SiPh2:HSiPh3 = 1.00:17.2:119). As a consequence, trihexylsilane is approximately two orders of magnitude more reactive than triphenylsilane though hexylsilane and phenylsilane show similar reactivities. Tris(trimethylsilyl)silane is just slightly more reactive than trimethylsilane. Replacement of hydrogen by chlorine reduces the reactivity by one order of magnitude. Variation of the electrophilicities of the hydride abstractors does not affect the relative reactivities of the silanes, i.e., constant selectivity (Ritchie-type) relationships are encountered. Correlation equations are given, which permit the calculation of hydride transfer rates from hydrosilanes to any carbenium ion on the basis of pkR+ values or the ethanolysis rate constants of the corresponding alkyl chlorides.

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