83470-31-9Relevant academic research and scientific papers
A phosphoryl radical-initiated Atherton-Todd-type reaction under open air
Ou, Yingcong,Huang, Yuanting,He, Zhenlin,Yu, Guodian,Huo, Yanping,Li, Xianwei,Gao, Yang,Chen, Qian
supporting information, p. 1357 - 1360 (2020/02/11)
A phosphoryl radical-initiated Atherton-Todd-type reaction using air as the radical initiator and CHCl3 as the halogenating reagent for the phosphorylation of alcohols, phenols, and amines has been developed. This novel transformation provides a highly efficient route to important phosphinates, phosphinic amides, and phosphoramidates in up to 99% yield with a broad substrate scope under very mild conditions (48 examples).
Novel method for preparing phosphonate through oxidative dehydrogenation coupled reaction of copper-catalyzed diarylphosphine oxide and alcohol
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Paragraph 0019, (2020/12/14)
The invention provides a method for efficiently and highly selectively synthesizing phosphonate derivatives containing different substituted functional groups. According to the method, cuprous iodideis used as a catalyst, 2,2'-dipyridyl is used as a ligand, pyridine is used as an alkali, oxygen is used as an oxidant, diarylphosphine oxide and an alcohol compound are used as reaction substrates, and an organic solvent is added into a reaction system. The method has the advantages that the catalyst and the oxidant are cheap and easily available; substrate applicability is high; reaction conditions are mild, safe and reliable; the selectivity of the obtained target products is close to 100%; and the yield of the target products is as high as 90% or above. The method overcomes the defects ofpoor reaction selectivity, complex reaction steps, low yield, need for reagents harmful to the environment and the like in the traditional synthesis of phosphonate derivatives, and has favorable industrial application prospects. The invention also provides the corresponding phosphonate derivatives containing different substituted functional groups.
Electrochemical Dehydrogenative Phosphorylation of Alcohols for the Synthesis of Organophosphinates
Deng, Lingling,Wang, Yang,Mei, Haibo,Pan, Yi,Han, Jianlin
, p. 949 - 956 (2019/01/14)
An eco-friendly and efficient method for the synthesis of organophosphinates via an electrochemical cross-dehydrogenative-coupling reaction between alcohols and secondary phosphine oxides has been developed. This electrochemical reaction was conducted at
Electrochemical Dehydrogenative Coupling of Alcohols with Hydrogen Phosphoryl Compounds: A Green Protocol for P?O Bond Formation
Li, Qian-Yu,Swaroop, Toreshettahally R.,Hou, Cheng,Wang, Zi-Qiang,Pan, Ying-Ming,Tang, Hai-Tao
supporting information, p. 1761 - 1765 (2019/02/20)
This study reports the environment-friendly electrochemical transformation of structurally diverse phosphorus compounds and alcohol into phosphonates in the presence of ammonium iodide as electrolyte and redox catalyst in acetonitrile at ambient temperature. This method for P?O bond formation exhibits remarkable features, such as transition metal- and oxidant-free conditions. A reliable mechanism is proposed after control and cyclic voltammetry experiments. (Figure presented.).
DIARYLPHOSPHINIC AZIDES. PHOTOCHEMICAL REACTIONS INCLUDING REARRANGEMENT IN METHANOL
Harger, Martin J.P.,Westlake, Sally
, p. 1511 - 1516 (2007/10/02)
On photolysis in methanol the diarylphosphinic azides Ar2P(O)N3 (Ar=phenyl, p-tolyl, p-anisyl, p-chlorophenyl) rearrange with loss of nitrogen to form (monomeric) metaphosphonimidates which are trapped by the solvent to give methyl NP-diarylphosphonamidates (7) (41-53percent).Diarylphosphinic amides (18-42percent) are also usually formed, presumably from (triplet) nitrenes.The limited evidence available suggests that the rearrangements take place directly from the photo-excited azides rather than via (singlet) nitrene intermediates.One of the products of rearrangement, methyl NP-di(p-chlorophenyl)phosphonamidate, suffers extensive photochemical dechlorination giving methyl N-phenyl-P-p-chlorophenylphosphonamidate.
