Matthew L. Clarke scite author profile

The trivalent metal cations Al(3+) , Cr(3+) , and Fe(3+) were each introduced, together with Sc(3+) , into MIL-100(Sc,M) solid solutions (M=Al, Cr, Fe) by direct synthesis. The substitution has been confirmed by powder X-ray diffraction (PXRD) and solid-state NMR, UV/Vis, and X-ray absorption (XAS) spectroscopy. Mixed Sc/Fe MIL-100 samples were prepared in which part of the Fe is present as α-Fe2 O3 nanoparticles within the mesoporous cages of the MOF, as shown by XAS, TGA, and PXRD. The catalytic activity of the mixed-metal catalysts in Lewis acid catalysed Friedel-Crafts additions increases with the amount of Sc present, with the attenuating effect of the second metal decreasing in the order Al>Fe>Cr. Mixed-metal Sc,Fe materials give acceptable activity: 40 % Fe incorporation only results in a 20 % decrease in activity over the same reaction time and pure product can still be obtained and filtered off after extended reaction times. Supported α-Fe2 O3 nanoparticles were also active Lewis acid species, although less active than Sc(3+) in trimer sites. The incorporation of Fe(3+) into MIL-100(Sc) imparts activity for oxidation catalysis and tandem catalytic processes (Lewis acid+oxidation) that make use of both catalytically active framework Sc(3+) and Fe(3+) . A procedure for using these mixed-metal heterogeneous catalysts has been developed for making ketones from (hetero)aromatics and a hemiacetal.

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Highly electron rich alkyl- and dialkyl-N-pyrrolidinyl phosphines: an evaluation of their electronic and structural properties

Clarke

Holliday

Slawin

et al. 2002

J. Chem. Soc., Dalton Trans.

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Hydrogenation of Aldehydes, Esters, Imines, and Ketones Catalyzed by a Ruthenium Complex of a Chiral Tridentate Ligand

2006

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A noVel ruthenium complex prepared from a chiral tridentate amine functionalized phosphine has been characterized by X-ray crystallography and been found to be actiVe in the hydrogenation of an unprecedented range of CdO and CdN double bonds, including the enantioselectiVe hydrogenation and transfer hydrogenation of normally unreactiVe bulky ketones with up to 90% ee.Reduction of CdO and CdN double bonds using molecular hydrogen is, due to its low cost and complete atom efficiency, a very important process in industrial organic syntheses. 1-3 There has consequently been a massive research effort aimed at developing homogeneous catalysts that can carry out this goal with high efficiency, chemoselectivity, and, in the case of prochiral ketones, enantioselectivity. Asymmetric hydrogenation of -keto esters and related substrates has been an industrial process for some time. 3 Homogeneous hydrogenation of unfunctionalized ketones could not be carried out with sufficient efficiency or chemoselectivity until Noyori's pioneering research on ruthenium complexes containing both diphosphine and diamine ligands. 4 These catalysts are highly chemoselective for CdO bonds, 5 show industrially relevant turnover numbers, and if the catalyst shown in Figure 1 is used, extremely high enantioselectivity for a range of acetophenone derivatives. Since Noyori's publications, several other catalysts have appeared that are based on the same design blueprint and have also given excellent results for reduction of acetophenone derivatives. [6][7][8][9][10] The key to the massively enhanced reactivity relative to that of simple Ru-phosphine catalysts is proposed to be the unique mechanism in which the substrate hydrogen bonds to the NH functionality in the diamine ligand. 11,12 However, [Ru(BINAP)(DAIPEN)Cl 2 ] and related catalysts do have some important limitations and are far less effective for the hydrogenation of tetralones, dialkyl ketones, bulky ketones, and some heterocyclic ketones and imines. We therefore initiated a project aimed at successfully hydrogenating these difficult substrates, with the general impression that a departure from the [Ru(diphosphine)(diamine)Cl 2 ] blueprint would be required. In this communication, we report preliminary results showing the promise of ruthenium complexes of chiral tridentate ligands as hydrogenation catalysts. Phosphine-amine ligands have provided some interesting niche applications in catalysis, 13-15 and given the absence of data on hydrogenation catalysis using tridentate ligands, 16,17 ruthenium complexes of tridentate P ∧ N ∧ NH 2 type ligands seemed worthy of investigation. This type of ligand could form octahedral ruthenium complexes with a more open coordination environment, thus increasing substrate scope or reactivity in hydrogenation. Another feature of interest was applying a single ligand to play the roles carried out by both diphosphine and diamine ligands in Noyori catalysts. [18][19][20] Ligand 1 is readily available in both racemic and enantiomerically pure forms from chea...

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Matthew L. Clarke

Remarkable Lewis acid catalytic performance of the scandium trimesate metal organic framework MIL-100(Sc) for C–C and CN bond-forming reactions

The carbonyl ene reaction

Mixed‐Metal MIL‐100(Sc,M) (M=Al, Cr, Fe) for Lewis Acid Catalysis and Tandem CC Bond Formation and Alcohol Oxidation

Highly electron rich alkyl- and dialkyl-N-pyrrolidinyl phosphines: an evaluation of their electronic and structural properties

Hydrogenation of Aldehydes, Esters, Imines, and Ketones Catalyzed by a Ruthenium Complex of a Chiral Tridentate Ligand

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