65868-38-4

Upstream product

• 75-77-4 chloro-trimethyl-silane 
• 1015-28-7 dimethyl (2-oxo-2-phenylethyl)phosphonate 
• 1795-31-9 tris(trimethylsilyl) phosphite 
• 70-11-1 α-bromoacetophenone 
• 3453-00-7 diethyl benzoylmethylphosphonate 

Relevant academic research and scientific papers

REAGENT FOR TESTING PURIFICATION CAPACITY OF RADIOACTIVE GAS IN NUCLEAR POWER PLANT, PREPARATION METHOD THEREOF AND IODIDE FILTER TESTING EQUIPMENT USING THIS REAGENT

Disclosed are a reagent for testing the purification capacity of a radioactive gas in a nuclear power plant, preparation method thereof and an iodide filter testing equipment using this reagent. The reagent is prepared by mixing methyl phosphate compound or dimethyl acetal compound, acetonitrile, trimethyl chlorosilane and radioactive iodine sources and carrying out a reaction at a temperature of 20°C-50 °C under an inert gas for 10-40 min. The prepared products except methyl iodide are non-toxic or little toxic to the nuclear grade impregnated activated carbon in the iodide filter.

Dealkylation of phosphonate esters with chlorotrimethylsilane

Chlorotrimethylsilane completely dealkylates phosphonate esters at elevated temperature in a sealed reaction vessel. These conditions are tolerated by a variety of functional groups and lead to high conversions of dimethyl, diethyl and diisopropyl phosphonates to their corresponding phosphonic acids.

Dealkylation Reaction of Acetals, Phosphonate, and Phosphate Esters with Chlorotrimethylsilane/Metal Halide Reagent in Acetonitrile, and Its Application to the Synthesis of Phosphonic Acids and Vinyl Phosphates

A mild and efficient method has been developed for carbon-oxygen bond cleavage using chlorotrimethylsilane/sodium iodide in acetonitrile.It was applied to synthetic transformation under nonaqueous and neutral conditions, such as acetal deprotection and the synthesis of phosphonic acids from the corresponding dialkyl phosphonates via methanolysis of their silyl esters.Effectiveness of various kinds of metal or ammonium iodides for this type of dealkylation was examined in the acetonitrile solution by 1H NMR.Satisfactory results were also obtained with lithium or potassium iodide in place of sodium iodide.However, copper(I) or quarternary ammonium iodide was ineffective.Chlorotrimethylsilane/lithium bromide in acetonitrile is effective for selective dealkylation of multifunctional phosphonic esters or dialkyl vinyl phosphates.

Silyl Phosphites. 15. Reactions of Silyl Phosphites with α-Halo Carbonyl Compounds. Elucidation of the Mechanism of the Perkow Reaction and Related Reactions with Confirmed Experiments

The reactions of silyl phosphites, i.e., tris(trimethylsilyl)phosphite (1), diethyl trimethylsilyl phosphite (11), and bis(trimethylsilyl) ethyl phosphite (12), with a variety of α-halo carbonyl compounds gave the 1:1 carbonyl addition products (6, 13, and 14), enol phosphates (5 and 26), and/or 2-oxophosphonates (4 and 25).Substituents on the phosphites and the α-halo carbonyl compounds have influenced the product ratios.The results of these reactions strongly suggest that the Perkow reaction proceeds via an initial attack of phosphite on the carbonyl carbon of the α-halo carbonyl compound.Treatment of bis(trimethylsilyl) 1--2-halo phosphonates (6) with sodium methoxide in methanol followed by retrimethylsilylation gave bis(trimethylsilyl) 1,2-epoxy phosphonates (17), bis(trimethylsilyl) 2-oxo phosphonates (4), and bis(trimethylsilyl) methyl phosphate (21).On the other hand, diethyl 1-hydroxy-2-halo phosphonates (22) were converted by treatment with different bases to 1,2-epoxy phosphonates (23) predominantly in good yields.When some of tri-n-butyltin alkoxides were used as bases, enol phosphates (26) were obtained selectively.Several bis(trimethylsilyl) esters obtained in the above reactions were successfully converted to the corresponding monoanilinium salts in high yields by treatment with aniline-containing alcohols.