I focus on ChemE applications of 3D printing, energy optimisation, decarbonisation of heavy industry, and domestic production of niche products.
Qualifications & Memberships
My overarching goal is to improve the sustainability of mankind by finding economic ways to eliminate fossil fuels from heavy industry, optimise energy usage, and develop better processes for the circular economy.
My research interests are in high-temperature electrolytic reduction of metals, domestic production of maple syrup, additive manufacturing of structured catalyst and adsorbent supports, mineral extraction from domestic resources, catalysis, and reactor modelling.
I am studying the feasibility of using high-temperature electrolysis to produce titanium metal from iron-sands slag. In addition, I am investigating other metal/ore systems that may benefit from molten oxide electrolysis
I am researching the economic potential, and best locations in New Zealand for maple tree plantations in order to commercially produce maple sap, and investigating alternative processes to vastly improve the energy cost associated with sap concentration to syrup. The research scope will expand to birch and other native tree syrups.
I am investigating optimized structured catalyst and adsorbent supports, for example to increase heat transfer and surface area while minimizing pressure drop, and using additive manufacturing as a means to build and experimentally confirm the structure-property relationships. This investigation is coupled to current research on numerical modelling of steam methane reformers.
I am developing low carbon processes to extract MgO from olivine to be used as a substitute for Portland cement. I am investigating the economic feasibility of direct reduction of iron using hydrogen. Cement and steel combined contribute about 16% of global man-made CO2 emissions.
- Baharudin L., Luthfi AAI., Watson M. and Yip ACK. (2021) Process intensification in multifunctional reactors: A review of multi-functionality by catalytic structures, internals, operating modes, and unit integrations. Chemical Engineering and Processing: Process Intensification 168 108561 http://dx.doi.org/10.1016/j.cep.2021.108561.
- Martin-Treceno S., Allanore A., Bishop C., Marshall A. and Watson M. (2021) Implications of the direct use of slag from ironmaking processes as a molten oxide electrolyte. JOM http://dx.doi.org/10.1007/s11837-021-04681-3.
- Martin-Treceno S., Hughes T., Weaver N., Marshall A., Watson M. and Bishop C. (2021) Electrochemical study on the reduction of Si and Ti from molten TiO2 − SiO2 − Al2O3 − MgO − CaO slag. Journal of The Electrochemical Society http://dx.doi.org/10.1149/1945-7111/ac0301.
- Martin-Treceno S., Weaver N., Allanore A., Bishop CM., Marshall AT. and Watson MJ. (2021) Corrigendum to “Electrochemical behaviour of titanium-bearing slag relevant for molten oxide electrolysis” [Electrochimica Acta 354 (2020) 136619] (Electrochimica Acta (2020) 354, (S0013468620310124), (10.1016/j.electacta.2020.136619)). Electrochimica Acta 373 http://dx.doi.org/10.1016/j.electacta.2021.137939.
- Nesbitt S., Watson M. and Golovko V. (2021) Size effect in Hydrogenation of Nitroaromatics using Support-immobilized Atomically Precise Gold Clusters. The Journal of Physical Chemistry C: Energy Conversion and Storage, Optical and Electronic Devices, Interfaces, Nanomaterials, and Hard Matter http://dx.doi.org/10.1021/acs.jpcc.0c08895.