Pyrroles are structurally important heterocycles. However, the synthesis of polysubstituted pyrroles is often challenging. Here, we report a multicomponent, Ti-catalysed formal [2+2+1] reaction of alkynes and diazenes for the oxidative synthesis of penta- and trisubstituted pyrroles: a nitrenoid analogue to classical Pauson-Khand-type syntheses of cyclopentenones. Given the scarcity of early transition-metal redox catalysis, preliminary mechanistic studies are presented. Initial stoichiometric and kinetic studies indicate that the mechanism of this reaction proceeds through a formally Ti(II)/Ti(IV) redox catalytic cycle, in which an azatitanacyclobutene intermediate, resulting from [2+2] alkyne + Ti imido coupling, undergoes a second alkyne insertion followed by reductive elimination to yield pyrrole and a Ti(II) species. The key component for catalytic turnover is the reoxidation of the Ti(II) species to a Ti(IV) imido via the disproportionation of an η(2)-diazene-Ti(II) complex.
The ability of various group 10 α-diimine and salicylaldimine polymerization catalysts to undergo chain transfer with main group metal alkyls during ethylene polymerization has been investigated in depth. The catalyst systems with the most efficient chain transfer were found to be cationic (α-diimine)Ni catalysts paired with dialkyl zinc chaintransfer reagents, in which all growing polymeryl chains were transferred to Zn on the basis of 13 C NMR analysis. In these systems, chain transfer was found to be dependent on the sterics of both the catalyst and the chain-transfer reagent (CTR). When less sterically encumbered catalysts or CTRs were utilized, the relative rate of bimetallic chain transfer to chain propagation was increased; however, in cases where chain termination via β-H elimination was extremely rapid, chain transfer to Zn was kinetically not viable. Importantly, chain transfer from (α-diimine)Ni catalysts to Zn alkyls is also very sensitive to the strength of the Zn−C bond: ZnMe 2 (186 kJ/mol) is a significantly poorer chain-transfer reagent than ZnEt 2 (157 kJ/mol), despite being less sterically encumbered. Finally, the nature of the catalyst counteranion (MAO or B(ArF) 4 − ArF = 3,5-(CF 3 ) 2 C 6 H 3 ) does not have a significant impact on the rate of chain transfer to ZnR 2 relative to propagation, indicating that the same factors that determine propagation rates also determine bimetallic chain-transfer rates.
The effect of proximal Zn halides on Ni-catalyzed ethylene polymerization is reported in this work. A series of (NON)NiLX (NON = 2,6-bis-((2,6-diisopropylphenyl)imino)methyl phenoxide; LX = methallyl or L = py, X = tolyl, 2-4) ethylene polymerization precatalysts have been synthesized, as well as a heterobimetallic Ni/Zn complex, (NON)Ni(CH)ZnBr (5). Each precatalyst could be activated (or promoted) by ZnX (X = Cl, Br, Et) to polymerize ethylene. In situ recruitment of ZnX by the free imine binding pocket of the NON complexes results in the generation of heterobimetallic active species that produce lower M polyethylene than monometallic controls. Room temperature ZnX-promoted polymerizations with these catalysts resulted in bimodal M distributions that result from different catalyst speciation: "dangling" imine-ligated ZnX species yield higher M polymer while N,O-chelated ZnX species yield lower M polymer. Running polymerizations at higher temperature yields in only lower M polymer resulting from exclusive formation of the thermodynamically favored N,O chelated Ni/Zn heterobimetallic. DFT calculations indicate that this bridging bimetallic complex undergoes β-H elimination more facilely than monometallic Ni analogues, resulting in lower molecular weight polymers.
Indium phosphide nanocrystals (InP NCs) with diameters ranging from 2 to 5 nm were synthesized with a scalable, flow-through, nonthermal plasma process at a rate ranging from 10 to 40 mg/h. The NC size is controlled through the plasma operating parameters, with the residence time of the gas in the plasma region strongly influencing the NC size. The NC size distribution is narrow with the standard deviation being less than 20% of the mean NC size. Zinc sulfide (ZnS) shells were grown around the plasma-synthesized InP NCs in a liquid phase reaction. Photoluminescence with quantum yields as high as 15% were observed for the InP/ZnS core-shell NCs.
Oleate-capped CdS nanocrystals (NCs) dispersed in dichloromethane were found to quench the excited-state fluorescence of the terthiophene derivative 3′,4′-dibutyl-5″-phenyl-[2,2′:5′,2″-terthiophene]-5-carboxylic acid (1-CO 2 H). Infrared and 1H NMR spectroscopies provided evidence that 1-CO 2 H substitutes for oleate on the surface of the CdS NCs. Upon binding, the fluorescence of 1-CO 2 H is quenched, and the 1H NMR lines from 1-CO 2 H are broadened. The importance of the carboxylate group in binding to the CdS NC was further established by examining the behavior of a similar fluorophore where the carboxylic acid group was replaced with a bromo substituent (1-Br). The CdS NCs had no influence on the fluorescence intensity or NMR line shapes of 1-Br. For 1-CO 2 H, Stern–Volmer plots indicated a nearly linear increase in I 0/I as the CdS NCs’ concentration was increased, but as the dye/NC ratio reached ∼20/1, I 0/I reached a maximum of ∼8 and began to decrease. By a dye/NC ratio of 2/1, the I 0/I reached a steady value of ∼2.5. The peak in the Stern–Volmer plot at a 20/1 ratio was consistent with a maximum in the contribution from concentration quenching at this coverage. On the basis of the appearance of the dye’s radical cation spectrum at low dye/NC ratios, ultrafast transient absorption spectroscopy confirmed electron transfer from the singlet excited state of the dye to the CdS NC with a lifetime of 16 ps. At higher dye/NC ratios, the signal from the radical cation was much less dominant, and the decay of the singlet excited state was dominated by the concentration quenching process having a 1 ps lifetime.
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