29848-60-0Relevant academic research and scientific papers
Selective C-F Functionalization of Unactivated Trifluoromethylarenes
Vogt, David B.,Seath, Ciaran P.,Wang, Hengbin,Jui, Nathan T.
, p. 13203 - 13211 (2019/09/03)
Fluorinated organic molecules are pervasive within the pharmaceutical and agrochemical industries due to the range of structural and physicochemical properties that fluorine imparts. Currently, the most abundant methods for the synthesis of the aryl-CF2 functionality have relied on the deoxyfluorination of ketones and aldehydes using expensive and poorly atom economical reagents. Here, we report a general method for the synthesis of aryl-CF2R and aryl-CF2H compounds through activation of the corresponding trifluoromethyl arene precursors. This strategy is enabled by an endergonic electron transfer event that provides access to arene radical anions that lie outside of the catalyst reduction potential. Fragmentation of these reactive intermediates delivers difluorobenzylic radicals that can be intercepted by abundant alkene feedstocks or a hydrogen atom to provide a diverse array of difluoalkylaromatics.
Sandmeyer difluoromethylation of (hetero-)arenediazonium salts
Matheis, Christian,Jouvin, Kvin,Goossen, Lukas J.
supporting information, p. 5984 - 5987 (2015/01/08)
A Sandmeyer-type difluoromethylation process has been developed that allows the straightforward conversion of (hetero-)arenediazonium salts into the corresponding difluoromethyl (hetero-)arenes under mild conditions. The actual difluoromethylating reagent, a difluoromethyl-copper complex, is formed in situ from copper thiocyanate and TMS-CF2H. The diazonium salts are either preformed or generated in situ from broadly available aromatic amines.
A two-component small molecule system for activity-based detection and signal amplification: Application to the visual detection of threshold levels of Pd(II)
Baker, Matthew S.,Phillips, Scott T.
, p. 5170 - 5173 (2011/05/19)
A detection and signal amplification strategy aimed toward threshold diagnostic assays for use in resource-limited settings is described. The strategy employs two small molecule reagents that work in tandem. One reagent detects a specific analyte, while the second amplifies a colorimetric readout autocatalytically. The strategy is demonstrated using palladium(II) as a model analyte.
