Get 20M+ Full-Text Papers For Less Than $1.50/day. Start a 14-Day Trial for You or Your Team.

Learn More →

Synthesis and reactions of 2,2,2‐trihaloethyl α‐hydroxyiminobenzylphosphonates. The influence of the ester group on the chemistry of phosphonates

Synthesis and reactions of 2,2,2‐trihaloethyl α‐hydroxyiminobenzylphosphonates. The influence of... Arbuzov reactions of diethyl 2,2,2‐trihaloethyl phosphites (3) with benzoyl chloride afforded ethyl 2,2,2‐trihaloethyl benzoylphosphonates (4). The reactions of 4 with NH2OH.HCl led to the formation of methyl benzoate and ethyl methyl H‐phosphonate as a result of alcoholysis of 4, followed by alkoxy group exchange. Methanol solutions of benzoylphosphonates 4 were found by 31P NMR spectroscopy to contain considerable proportions of hemiacetals, 7, which undergo base‐catalyzed CP bond cleavage. The formation of hemiacetals from benzoylphosphonates 4 is suppressed in 2‐propanol, and in this solvent the corresponding oximes 2 could be obtained in good yields. Reactions of methyl benzoylphosphonochloridate (10) with 2,2,2‐trihaloethanols, in CH2Cl2, gave methyl 2,2,2‐trihaloethyl benzoylphosphonates (11) which could be converted directly to oximes 12 by NH2OH.HCl in a one‐pot procedure. In contrast to the previously studied dimethyl (E)‐α‐hydroxyiminobenzylphosphonate, which underwent thermal Beckmann rearrangement to afford N‐benzoylphosphoramidates, both (E) and (Z)‐trihaloethyl esters 2 and 12 underwent fragmentation to benzonitrile and to the corresponding dialkyl hydrogen phosphate, reflecting the increased electrophilicity of the phosphorus in these compounds. Demethylation of methyl esters 12 was effected smoothly by iodide or bromide ions to yield benzoylphosphonate salts 15, which in turn were converted to oxime salts 14 by treatment with hydroxylamine. In contrast, attempted deethylation of ethylesters 2 in refluxing acetonitrile led to benzonitrile and pyrophosphate type product as indicated by 31P spectroscopic examination of the reaction mixture. Oxime salts 14 behaved similarly when heated. Acidification of lithium 2,2,2‐trifluoroethyl α‐hydroxyiminobenzylphosphonate (14a) gave the corresponding hydrogen trifluoroethyl phosphonate (19a). The fragmentation of 19a in 0.6 N ethanolic hydrogen chloride to ethyl trifluoroethyl hydrogen phosphate and benzonitrile at room temperature had a T1/2 value of approx 18 hours, which is greater by a factor of 2 than that of the corresponding methyl ester. When the fragmentation of 19 was carried out in solvent mixtures of either water with methanol or 2‐propanol, or methanol with tbutanol, the composition of the solvents was reflected in the products, indicating a dissociative type mechanism, involving metaphosphate as reactive intermediates. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Heteroatom Chemistry Wiley

Synthesis and reactions of 2,2,2‐trihaloethyl α‐hydroxyiminobenzylphosphonates. The influence of the ester group on the chemistry of phosphonates

Heteroatom Chemistry , Volume 3 (3) – Jan 1, 1992

Loading next page...
 
/lp/wiley/synthesis-and-reactions-of-2-2-2-trihaloethyl-zX6h2EcKk9

References (11)

Publisher
Wiley
Copyright
Copyright © 1992 Wiley Subscription Services
ISSN
1042-7163
eISSN
1098-1071
DOI
10.1002/hc.520030310
Publisher site
See Article on Publisher Site

Abstract

Arbuzov reactions of diethyl 2,2,2‐trihaloethyl phosphites (3) with benzoyl chloride afforded ethyl 2,2,2‐trihaloethyl benzoylphosphonates (4). The reactions of 4 with NH2OH.HCl led to the formation of methyl benzoate and ethyl methyl H‐phosphonate as a result of alcoholysis of 4, followed by alkoxy group exchange. Methanol solutions of benzoylphosphonates 4 were found by 31P NMR spectroscopy to contain considerable proportions of hemiacetals, 7, which undergo base‐catalyzed CP bond cleavage. The formation of hemiacetals from benzoylphosphonates 4 is suppressed in 2‐propanol, and in this solvent the corresponding oximes 2 could be obtained in good yields. Reactions of methyl benzoylphosphonochloridate (10) with 2,2,2‐trihaloethanols, in CH2Cl2, gave methyl 2,2,2‐trihaloethyl benzoylphosphonates (11) which could be converted directly to oximes 12 by NH2OH.HCl in a one‐pot procedure. In contrast to the previously studied dimethyl (E)‐α‐hydroxyiminobenzylphosphonate, which underwent thermal Beckmann rearrangement to afford N‐benzoylphosphoramidates, both (E) and (Z)‐trihaloethyl esters 2 and 12 underwent fragmentation to benzonitrile and to the corresponding dialkyl hydrogen phosphate, reflecting the increased electrophilicity of the phosphorus in these compounds. Demethylation of methyl esters 12 was effected smoothly by iodide or bromide ions to yield benzoylphosphonate salts 15, which in turn were converted to oxime salts 14 by treatment with hydroxylamine. In contrast, attempted deethylation of ethylesters 2 in refluxing acetonitrile led to benzonitrile and pyrophosphate type product as indicated by 31P spectroscopic examination of the reaction mixture. Oxime salts 14 behaved similarly when heated. Acidification of lithium 2,2,2‐trifluoroethyl α‐hydroxyiminobenzylphosphonate (14a) gave the corresponding hydrogen trifluoroethyl phosphonate (19a). The fragmentation of 19a in 0.6 N ethanolic hydrogen chloride to ethyl trifluoroethyl hydrogen phosphate and benzonitrile at room temperature had a T1/2 value of approx 18 hours, which is greater by a factor of 2 than that of the corresponding methyl ester. When the fragmentation of 19 was carried out in solvent mixtures of either water with methanol or 2‐propanol, or methanol with tbutanol, the composition of the solvents was reflected in the products, indicating a dissociative type mechanism, involving metaphosphate as reactive intermediates.

Journal

Heteroatom ChemistryWiley

Published: Jan 1, 1992

There are no references for this article.