1563-90-2Relevant articles and documents
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Robson,Reinhart
, p. 498,2456 (1955)
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Spectrophotometric Analysis of Ternary Uranyl Systems to Replace Tri-N-butyl Phosphate (TBP) in Used Fuel Reprocessing
Canner, Adam J.,Harwood, Laurence M.,Cowell, Joseph,Babra, Jasraj S.,Brown, Solomon F.,Ogden, Mark D.
, p. 52 - 67 (2020/01/28)
In this report, the interaction of monoamide/diamide and monoamide/diglycolamide mixtures with UO22+ are investigated in pH = 1 methanolic nitric acid media. These monoamides include N,N-dimethylacetamide (DMAA), N,N-diethylacetamide (DEAA), N,N-dibutylacetamide (DBAA) and N,N-dibutylbutanamide (DBBA). N,N,N′N′-tetraethylmalonamide (TEMA) and N,N,N′,N′-tetraethyldiglycolamide (TEDGA), which were chosen as model diamides and diglycolamides, respectively. Complex stability constants for each ligand were modelled using the Stability Quotients Using Absorbance Data program using UV–visible data. Complex stoichiometry of ligand mixtures was determined using Job plots and UV–Vis spectrometry. Monoamides were confirmed to produce only disolvate complexes with UO22+ in solution. The log10(K) values for monoamides were found to be independent of amine-side chain length, but were slightly dependent on the carbonyl-side chain length. TEDGA was found to produce multiple uranyl complexes in solution. Job plot data indicated that the uranyl cation strongly prefers to bond either only with the monoamide or diamide in ternary monoamide–diamide–UO2 systems. Monoamide–diglycolamide–UO2 systems were more complicated, with Job plot data indicating the potential for multiple ternary species being present is dependent on the monoamide structure.
1,1-Diacyloxy-1-phenylmethanes as versatile N-acylating agents for amines
Chapman, Robert. S.L.,Tibbetts, Joshua. D.,Bull, Steven. D.
, p. 5330 - 5339 (2018/06/15)
1,1-Diacyloxy-1-phenylmethanes and 1-pivaloxy-1-acyloxy-1-phenylmethanes have been used as bench stable N-acylating reagents for primary and secondary amines and anilines under solvent-free conditions to afford their corresponding amides in good yield.
Amide bond formation through iron-catalyzed oxidative amidation of tertiary amines with anhydrides
Li, Yuanming,Ma, Lina,Jia, Fan,Li, Zhiping
, p. 5638 - 5646 (2013/07/26)
A general and efficient method for amide bond synthesis has been developed. The method allows for synthesis of tertiary amides from readily available tertiary amines and anhydrides in the presence of FeCl2 as catalyst and tert-butyl hydroperoxide in water (T-Hydro) as oxidant. Mechanistic studies indicated that the in situ-generated α-amino peroxide of tertiary amine and iminium ion act as key intermediates in this oxidative transformation.