Your search keyword '"Griffiths, Anthony"' showing total 4 results

1. Amine-modified polyionic liquid supports enhance the efficacy of PdNPs for the catalytic hydrogenation of CO2 to formate.

Author

Paterson, Reece, Fahy, Luke E., Arca, Elisabetta, Dixon, Casey, Wills, Corinne Y., Yan, Han, Griffiths, Anthony, Collins, Sean M., Wu, Kejun, Bourne, Richard A., Chamberlain, Thomas W., Knight, Julian G., and Doherty, Simon

Subjects

CATALYTIC hydrogenation, POLYMERIZED ionic liquids, CONDUCTING polymers, IONIC liquids, BENZYLAMINE

Abstract

Palladium nanoparticles stabilised by aniline modified polymer immobilised ionic liquid is a remarkably active catalyst for the hydrogenation of CO2 to formate; the initial TOF of 500 h−1 is markedly higher than either unmodified catalyst or its benzylamine and N,N-dimethylaniline modified counterparts and is among the highest to be reported for a PdNP-based catalyst. [ABSTRACT FROM AUTHOR]

Published

2023

2. Amino‐Modified Polymer Immobilized Ionic Liquid Stabilized Ruthenium Nanoparticles: Efficient and Selective Catalysts for the Partial and Complete Reduction of Quinolines.

Author

Alharbi, Adhwa A., Wills, Corinne, Chamberlain, Thomas W., Bourne, Richard A., Griffiths, Anthony, Collins, Sean M., Wu, Kejun, Mueller, Pia, Knight, Julian G., and Doherty, Simon

Subjects

QUINOLINE, CONDUCTING polymers, PLATINUM nanoparticles, IONIC liquids, RUTHENIUM, HETEROGENEOUS catalysts, CATALYSTS

Abstract

RuNPs stabilised by amino‐decorated imidazolium‐based polymer immobilized ionic liquids catalyse the dimethylamine borane mediated reduction of quinolines to 1,2‐dihydroquinoline (DHQ) and 1,2,3,4‐tetrahydroquinoline (THQ). Partial reduction of 3‐substituted quinolines to the corresponding 1,2‐dihydroquinoline was achieved with 100 % selectivity in toluene under mild conditions. This is the first report of the selective partial reduction of 3‐substituted quinolines to the corresponding 1,2‐dihydroquinolines with a heterogeneous nanoparticle‐based catalyst. A wide range of substituted quinolines have also been reduced to the corresponding 1,2,3,4‐tetrahydroquinoline with high selectivity and good yields by adjusting the reaction time. The 1,2‐dihydroquinolines readily release dihydrogen in toluene at 60 °C in the absence of catalyst with no evidence for disproportionation and as such are potential organo‐hydride reagents. The initial TOF of 610 mol quinoline converted mol Ru−1 h−1 for the reduction of quinoline is among the highest to be reported for a metal nanoparticle‐based catalyst and the conversion of 96 % obtained after 4 h at 65 °C is significantly higher than its platinum nanoparticle counterpart PtNP@NH2‐PEGPIILS as well as 5 wt/% Ru/C, which only reached 9 % and 11 % conversion, respectively, at the same time. Hot filtration experiments showed that the active species was heterogeneous. [ABSTRACT FROM AUTHOR]

Published

2023

3. Highly efficient and selective partial reduction of nitroarenes to N-arylhydroxylamines catalysed by phosphine oxide-decorated polymer immobilized ionic liquid stabilized ruthenium nanoparticles.

Author

Paterson, Reece, Alharbi, Husam Y., Wills, Corinne, Chamberlain, Thomas W., Bourne, Richard A., Griffiths, Anthony, Collins, Sean M., Wu, Kejun, Simmons, Matthew D., Menzel, Robert, Massey, Alexander F., Knight, Julian G., and Doherty, Simon

Subjects

*PHOSPHINE oxides, *NITROAROMATIC compounds, *CONDUCTING polymers, *IONIC liquids, *RUTHENIUM, *STYRENE

Abstract

[Display omitted] • Ultrafine RuNPs stabilised by a phosphine oxide-modified polymer immobilized ionic liquid. • Complete selectivity for the partial reduction of aromatic and heteroaromatic nitroarenes to the corresponding N -arylhydroxylamine. • Highest initial turn over frequency to be reported for a RuNP catalysed partial reduction of nitrobenzene to N -phenylhydroxylamine. • Reduction of electron rich amino nitroarenes to the aniline proposed to occur via a quinondiimine-derived iminium. • High activity and selectivity retained over five reuses with only a minor reduction in conversion. RuNPs stabilised by a polymer immobilised ionic liquid derived from co-polymerisation of a PEG-substituted imidazolium-based styrene monomer and diphenyl(4-vinylphenyl)phosphine oxide, RuNP@O = PPh 2 -PEGPIILS, (2) is a remarkably efficient and selective catalyst for the hydrazine hydrate-mediated partial reduction of nitroarenes to the corresponding N -arylhydoxylamine. Near quantitative conversion to N -phenylhydroxylamine with > 99 % selectivity was obtained after only 2 h when the reaction was conducted at 25 °C in ethanol under an inert atmosphere using 0.1 mol% catalyst. Under these conditions, the composition-time profile showed that the reduction occurred via the direct pathway whereas reactions in air gave a mixture of azoxy-based products due to competing condensation resulting from reversible formation of N -phenylhydroxylamine. The initial TOF of 6,100 h−1 obtained after 10 min at 40 °C with 0.1 mol% 2 is among the highest to be reported for the metal nanoparticle catalysed reduction of nitrobenzene to N -phenylhydroxylamine and a significant improvement on 5 wt% Ru/C which gave a modest conversion of 21 % (initial TOF = 240 h−1) to a mixture of N -phenylhydroxylamine and aniline. A broad range of substituted N -aryl and N -heteroaryl nitroarenes were reduced to the corresponding N -arylhydroxylamine in high yield and with excellent selectivity by adjusting the reaction times. However, reduction of electron rich amino-substituted nitroarenes was extremely slow and resulted in reduction to the aniline with no evidence for the corresponding hydroxylamine. Complete reduction of amino substituted nitroarene is proposed to be facilitated by amine-assisted elimination of hydroxide from the hydroxylamine to afford a readily reducible quinondiimine-derived iminium intermediate that reacts with a surface hydride to liberate the amine. Under optimum conditions the catalyst could be reused five times for the reduction of nitrobenzene to N -phenylhydroxylamine with no detectable change in activity and only slight decrease in selectivity. [ABSTRACT FROM AUTHOR]

Published

2023

4. Heteroatom modified polymer immobilized ionic liquid stabilized ruthenium nanoparticles: Efficient catalysts for the hydrolytic evolution of hydrogen from sodium borohydride.

Author

Paterson, Reece, Alharbi, Adhwa A., Wills, Corinne, Dixon, Casey, Šiller, Lidja, Chamberlain, Thomas W., Griffiths, Anthony, Collins, Sean M., Wu, Kejun, Simmons, Matthew D., Bourne, Richard A., Lovelock, Kevin R.J., Seymour, Jake, Knight, Julian G., and Doherty, Simon

Subjects

*HETEROCHAIN polymers, *IONIC liquids, *HYDROLYSIS, *ISOTOPES, *VISCOSITY, *CATALYSTS

Abstract

• Ultrafine RuNPs are stabilised by amino-modified polymer immobilized ionic liquid. • High activity for hydrolytic evolution of hydrogen from NaBH 4. • Kinetic studies confirm the hydrolysis is first order in catalyst and hydride. • Kinetic isotope studies with H 2 O/D 2 O and NaBH 4 /NaBD 4 support the proposed mechanism. • High activity retained over five reuses with only a minor reduction in conversion. Ruthenium nanoparticles stabilised by polymer immobilized ionic liquids catalyse the hydrolytic release of hydrogen from sodium borohydride. The composition of the polymer influences performance and ruthenium nanoparticles stabilised by an amine-decorated imidazolium-based polymer immobilised ionic liquid (RuNP@NH 2 -PIILS) was the most efficient with a maximum initial turnover frequency (TOF) of 177 mole H2.mol Ru −1.min−1, obtained at 30°C with a catalyst loading of 0.08 mol%; markedly higher than that of 69 mol H2.mol Ru −1.min−1 obtained with 5 wt% Ru/C and one of the highest to be reported for a RuNP catalyst. The apparent activation energy (Ea) of 38.9 kJ mol−1 for the hydrolysis of NaBH 4 catalysed by RuNP@NH 2 -PIILS is lower than that for the other polymer immobilized ionic liquid stabilised RuNPs, which is consistent with its efficacy. Comparison of the initial rates of hydrolysis in H 2 O and D 2 O catalysed by RuNP@NH 2 -PIILS gave a primary kinetic isotope effect (k H / k D) of 2.3 which supports a mechanism involving rate limiting oxidative addition of one of the O-H bonds in a strongly hydrogen-bonded surface-coordinated [BH 3 H−]—-H 2 O ensemble. The involvement of a surface-coordinated borohydride is further supported by an inverse kinetic isotope effect of 0.65 obtained from a comparison of the initial rates for the hydrolysis of NaBH 4 and NaBD 4 under the conditions of catalysis i.e., at a high hydride/catalyst mole ratio. Interestingly though, when the comparison of the initial rates of hydrolysis of NaBH 4 and NaBD 4 was conducted in dilute solution with a hydride/catalyst mole ratio of 1 a kinetic isotope effect (k H / k D) of 2.72 was obtained; this would be more consistent with concerted activation of both an O-H and B-H bond in the rate limiting step, possibly via a concerted oxidative addition-hydride transfer in the surface-coordinated hydrogen-bonded ensemble. Catalyst stability and reuse studies showed that RuNP@NH 2 -PIILS retained 71% of its activity over five runs; the gradual drop in the initial TOF with run number appears to be due to passivation of the catalyst by the sodium borate by-product as well as an increase in viscosity of the reaction mixture rather than leaching of the catalyst. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022