1657-60-9Relevant articles and documents
Donor-activated alkali metal dipyridylamides: Co-complexation reactions with zinc alkyls and reactivity studies with benzophenone
Armstrong, David R.,Brouillet, Etienne V.,Kennedy, Alan R.,Garden, Jennifer A.,Granitzka, Markus,Mulvey, Robert E.,Trivett, Joshua J.
, p. 14409 - 14423 (2014)
Previously it was reported that activation of tBu2Zn by [(TMEDA)Na(μ-dpa)]2led to tert-butylation of benzophenone at the challenging para-position, where the sodium amide functions as a metalloligand towards tBu2Zn manifested in crystalline [{(TMEDA)Na(dpa)}2ZntBu2] (TMEDA is N,N,N′,N′-tetramethylethylenediamine, dpa is 2,2′-dipyridylamide). Here we find altering the Lewis donor or alkali metal within the metalloligand dictates the reaction outcome, exhibiting a strong influence on alkylation yields and reaction selectivity. Varying the former led to the synthesis of three novel complexes, [(PMDETA)Na(dpa)]2, [(TMDAE)Na(dpa)]2, and [(H6-TREN)Na(dpa)], characterised through combined structural, spectroscopic and theoretical studies [where PMDETA is N,N,N′,N′′,N′′-pentamethyldiethylenetriamine, TMDAE is N,N,N′,N′-tetramethyldiaminoethylether and H6-TREN is N′,N′-bis(2-aminoethyl)ethane-1,2-diamine]. Each new sodium amide can function as a metalloligand to generate a co-complex with tBu2Zn. Reacting these new co-complexes with benzophenone proved solvent dependent with yields in THF much lower than those in hexane. Most interestingly, sub-stoichiometric amounts of the metalloligands [(TMEDA)Na(dpa)]2and [(PMEDTA)Na(dpa)]2with 1 : 1, tBu2Zn-benzophenone mixtures produced good yields of the challenging 1,6-tert-butyl addition product in hexane (52% and 53% respectively). Although exchanging Na for Li gave similar reaction yields, the regioselectivity was significantly compromised; whereas the K system was completely unreactive. Replacing tBu2Zn with (Me3SiCH2)2Zn shut down the alkylation of benzophenone; in contrast, tBuLi generates only the reduction product, benzhydrol. Zincation of the parent amine dpa(H) generated the crystalline product [Zn(dpa)2], as structurally elucidated through X-ray crystallography and theoretical calculations. Although the reaction mechanism for the alkylation of benzophenone remains unclear, incorporation of the radical scavenger TEMPO (2,2,6,6-tetramethylpiperidine-N-oxyl radical) into the reaction system completely inhibits benzophenone alkylation.
Anomalous C-C bond cleavage in sulfur-centered cation radicals containing a vicinal hydroxy group
Li, Zaiguo,Kutateladze, Andrei G.
, p. 8236 - 8239 (2007/10/03)
1,3-Dithianyl cation radicals having α-hydroxy-neopentyl or similar groups in position 2, which are generated via oxidative photoinduced electron transfer, undergo anomalous fragmentation necessitating refinement of the accepted mechanism. Experimental and computational data support a rationale in which proton abstraction from the hydroxy group in the initial cation radical does not cause a Grob-like fragmentation, but rather produces a neutral radical species, the alkoxy radical, that undergoes fragmentation in either direction, i.e., cleaving the C-C bond to dithiane or to the tertiary alkyl group.
A comparative product investigation between Grignard reactions of benzophenone and coupling reactions of electrogenerated benzophenone radical anions and alkyl radicals in THF
Lund, Torben,Ohlrich, Ditte,Borling, Pernille
, p. 932 - 937 (2007/10/03)
The 1,6-to 1,2-addition product ratios of the Grignard reactions of benzophenone with t-, s- and n-C4H9MgCl have been compared with the corresponding ratios obtained by the electrolysis of benzophenone in presence of t-, s- and n-C4H9S+(CH3)2, ClO4-in THF. The Grignard reaction ratios 0.81, 0.50 and 0.19, respectively, were obtained whereas the corresponding electrolysis ratios were 2.26, 1.23 and 1.61. From this comparison of product ratios it is concluded that none of the Grignard reactions of benzophenone proceeds through a complete free coupling process of benzophenone radical anions and butyl radicals. The ET character of the Grignard reactions of benzophenone with t-, s- and n-C4H9MgCl was estimated to be 65, 61 and 26%, respectively.