Hammond, Ceri - Cardiff University

个人简介

BSc/MSc in Chemistry, Cardiff University (2004-2008, 1st class honours); PhD in Catalysis and Chemical Engineering, Cardiff Catalysis Institute (2008-2011, Prof. Graham J. Hutchings FRS); Post-doctoral Research Associate, Department of Chemical Engineering at ETH Zurich (2011-2014, Prof. Ive Hermans); Visiting Research Fellow, University College London/UK Catalysis Hub (2013-Present); University Research Fellow and Independent Research Group Leader, Cardiff Catalysis Institute (2014-Present) 1 - EFCATS 'Most Outstanding PhD Thesis' prize (biennial award, 2011-2013) 2 - Visiting Research Fellowship 2013-2015 (University College London/UK Catalysis Hub) 3 - Chancellor's Independent Research Fellowship 2014-2019 (Cardiff University) 4 - PhD Scholarship 2008-2011 (Cardiff University)

研究领域

Catalysis plays an essential role in physiology, nature, and the production of chemicals and fuels. Research in my group is situated at the interface of chemistry and chemical engineering, and focuses on the design and application of new heterogeneous catalysts for the production of energy and chemicals. Typically, a combination of crosscutting techniques is utilised in order to prepare novel (improved) and highly selective materials for new (established) catalytic processes. In depth kinetic and mechanistic analysis of the synthesised catalysts is combined with in situ spectroscopic analysis and theoretical models of the catalytic active sites, with the aim of developing i) molecular-level structure-activity relationships, and subsequently ii) tailor-made heterogeneous catalysts that are more active and selective on a macroscopic scale. In general, our research is focused on the fields of selective oxidations - particularly with more sustainable oxidants such as H2O2 and O2 - and acid catalysis, with C1-building blocks, alkanes, and bio-renewable substrates representing the starting molecules of interest.

近期论文

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Padovan, D., Al-Nayili, A. and Hammond, C. 2017. Bifunctional Lewis and Brønsted acidic zeolites permit the continuous production of bio-renewable furanic ethers. Green Chemistry (10.1039/C7GC00160F) pdf Hammond, C. 2017. Intensification studies of heterogeneous catalysts: probing and overcoming catalyst deactivation during liquid phase operation. Green Chemistry (10.1039/C7GC00163K) pdf Yakabi, K.et al. 2016. Selectivity and lifetime effects in zeolite-catalyzed Baeyer-Villiger oxidation investigated in batch and continuous flow. ChemCatChem 8(22), pp. 3490-3498. (10.1002/cctc.201600955) pdf Padovan, D.et al. 2016. Intensification and deactivation of Sn-Beta investigated in the continuous regime. Green Chemistry 2016(18), pp. 5041-5049. (10.1039/C6GC01288D) pdf Villa, A.et al. 2016. Characterisation of gold catalysts. Chemical Society Reviews 45(18), pp. 4953-4994. (10.1039/C5CS00350D) pdf Ab Rahim, M.et al. 2016. Low temperature selective oxidation of methane to methanol using titania supported gold palladium copper catalysts. Catalysis Science & Technology 6(10), pp. 3410-3418. (10.1039/C5CY01586C) Villa, A.et al. 2016. Depressing the hydrogenation and decomposition reaction in H2O2 synthesis by supporting gold-palladium nanoparticles on oxygen functionalized carbon nanofibers. Catalysis Science & Technology 6, pp. 694-697. (10.1039/C5CY01880C) Al-Nayili, A., Yakabi, K. and Hammond, C. 2016. Hierarchically porous BEA stannosilicates as unique catalysts for bulky ketone conversion and continuous operation. Journal of Materials Chemistry A 4, pp. 1373-1382. (10.1039/C5TA08709K) Dimitratos, N.et al. 2015. Effect of the preparation method of supported Au nanoparticles in the liquid phase oxidation of glycerol. Applied Catalysis A: General 514, pp. 267-275. (10.1016/j.apcata.2015.12.031) Hammond, C. and Tarantino, G. 2015. Switching off H2O2 decomposition during TS-1 catalysed epoxidation via post-synthetic active site modification. Catalysts 5(4), pp. 2309-2323. (10.3390/catal5042309) pdf Conrad, S.et al. 2015. Cover picture: silica-grafted SnIV catalysts in hydrogen-transfer reactions (ChemCatChem 20/2015). ChemCatChem 7(20), pp. 3188. (10.1002/cctc.201501018)