Mr James Hayward

2025

• Chan, C. d. C., Alsalem, L. F., Almalki, M., Bozhinovska, I., Hayward, J. S., Williams, S. S. N. and Bartley, J. K. 2025. Microwave-assisted degradation of azo dyes using NiO catalysts. Catalysts 15(8), article number: 702. (10.3390/catal15080702)
• Oh, R. et al. 2025. Electronic and compositional modulation of SMSI states for selective CO2 hydrogenation with rhodium catalysts. ACS Catalysis, pp. 12014-12024. (10.1021/acscatal.5c02436)
• Sun, J., Hayward, J. S., Barter, M., Slocombe, D. R. and Bartley, J. K. 2025. Microwave-assisted selective oxidation of propene over bismuth molybdate catalysts: the importance of catalyst synthesis methodology. Discover Catalysis 2(1), article number: 11. (10.1007/s44344-025-00014-7)
• Rabiu, H. S., Hayward, J. S. and Bartley, J. K. 2025. High surface area perovskite materials as functional catalyst supports for glycerol oxidation. Molecular Catalysis 572, article number: 114750. (10.1016/j.mcat.2024.114750)
• Filipini Ferreira, G., Pinto, L. F. R., Maciel Filho, R., Fregolente, L. V., Hayward, J. and Bartley, J. 2025. Ethanol-based transesterification of rapeseed oil with CaO Catalyst: process optimization and validation using microalgal lipids. Catalysis Letters 155, article number: 84. (10.1007/s10562-024-04921-6)

2024

• Ferreira, G. F., Ríos Pinto, L. F., Filho, R. M., Fregolente, L. V., Hayward, J. S. and Bartley, J. K. 2024. A comparison of monoglyceride production from microalgaelipids and rapeseed oil catalyzed by metal oxides. Chemistry-Sustainability-Energy-Materials 17(23), article number: e202400953. (10.1002/cssc.202400953)
• Sun, J., Hayward, J. S., Barter, M., Slocombe, D. R. and Bartley, J. K. 2024. Designing heterogeneous catalysts for microwave assisted selective oxygenation. ChemCatChem 16(19), article number: e202301586. (10.1002/cctc.202301586)
• Wallace, W. T., Hayward, J. S., Marsh, A. R. and Bartley, J. K. 2024. The antisolvent precipitation of CuZnOx mixed oxide materials using a choline chloride-urea deep eutectic solvent. Molecules 29(14), article number: 3357. (10.3390/molecules29143357)
• Oh, R. et al. 2024. Insights into CeO2 particle size dependent selectivity control for CO2 hydrogenation using Co/CeO2 catalysts. ACS Catalysis 14(2), pp. 897–906. (10.1021/acscatal.3c05139)

2023

• Hayward, J., Esquius, J. R., Richards, N., Jones, W., Hewes, D. and Bowker, M. 2023. Delaminated hydrotalcite precursors for green methanol synthesis. Catalysis Communications 179, article number: 106694. (10.1016/j.catcom.2023.106694)

2022

• Lawes, N. et al. 2022. Methanol synthesis from CO2 and H2 using supported Pd alloy catalysts.. Faraday Discussions (10.1039/D2FD00119E)
• Bowker, M. et al. 2022. The critical role of βPdZn alloy in Pd/ZnO catalysts for the hydrogenation of carbon dioxide to methanol. ACS Catalysis 12(9), pp. 5371-5379. (10.1021/acscatal.2c00552)

2021

• Wallace, W. T., Hayward, J. S., Ho, C., Marsh, A. R., Tariq, A. and Bartley, J. K. 2021. Triethylamine-water as a switchable solvent for the synthesis of Cu/ZnO catalysts for carbon dioxide hydrogenation to methanol. Topics in Catalysis 64, pp. 984-991. (10.1007/s11244-021-01457-6)
• Kennedy, J., Hayward, J., Davies, P. and Bowker, M. 2021. Hydrogen production by the photo-reforming of methanol and the photocatalytic water gas shift reaction. Journal of Physics: Energy 3(2), article number: 24007. (10.1088/2515-7655/abdd82)

2019

• Orlowski, I. et al. 2019. The hydrogenation of levulinic acid to γ-valerolactone over Cu-ZrO2 catalysts prepared by a pH-gradient methodology. Journal of Energy Chemistry 36, pp. 15-24. (10.1016/j.jechem.2019.01.015)

2017

• Hayward, J. S., Smith, P. J., Kondrat, S. A., Bowker, M. and Hutchings, G. J. 2017. The effects of secondary oxides on copper-based catalysts for green methanol synthesis. ChemCatChem 9(9), pp. 1655-1662. (10.1002/cctc.201601692)
• Niemantsverdriet, H. et al. 2017. Catalysis for fuels: general discussion. Faraday Discussions 197, pp. 165-205. (10.1039/C7FD90010D)
• Kondrat, S. A. et al. 2017. The effect of sodium species on methanol synthesis and water-gas shift Cu/ZnO catalysts: utilising high purity zincian georgeite. Faraday Discussions 197, pp. 287-307. (10.1039/C6FD00202A)
• Bahruji, H., Bowker, M., Jones, W., Hayward, J., Ruiz Esquius, J., Morgan, D. J. and Hutchings, G. J. 2017. PdZn catalysts for CO2 hydrogenation to methanol using chemical vapour impregnation (CVI). Faraday Discussions 197, pp. 309-324. (10.1039/C6FD00189K)

2016

• Iqbal, S. et al. 2016. Fischer Tropsch Synthesis using promoted cobalt-based catalysts. Catalysis Today 272, pp. 74-79. (10.1016/j.cattod.2016.04.012)

2013

• Hayward, J. 2013. Supported metal catalysts for the production of chemical precursors. PhD Thesis, Cardiff University.

2011

• Dummer, N., Bawaked, S. M., Hayward, J., Jenkins, R. L. and Hutchings, G. J. 2011. Reprint of: Oxidative dehydrogenation of cyclohexane and cyclohexene over supported gold, -palladium catalysts. Catalysis Today 160(1), pp. 50-54. (10.1016/j.cattod.2010.12.014)

2010

• Dummer, N., Bawaked, S. M., Hayward, J., Jenkins, R. L. and Hutchings, G. J. 2010. Oxidative dehydrogenation of cyclohexane and cyclohexene over supported gold, palladium and gold-palladium catalysts. Catalysis Today 154(1-2), pp. 2-6. (10.1016/j.cattod.2010.03.031)