Associate Professor Simon Smart
Associate Professor

Simon Smart

Email: 
Phone: 
+61 7 336 58591

Background

Overview:

Simon Smart is an Associate Professor in the School of Chemical Engineering at The University of Queensland. He is the UQ Director of the Net Zero Australia study and a Chief Investigator in the ARC Centre of Excellence for Green Electrochemical Transformation of CO2 (GETCO2). Simon completed his BE/BSc and PhD degrees in Chemical Engineering at The University of Queensland in 2003 and 2008 respectively. From 2008 until 2012, Simon was a research fellow in the Films and Inorganic Membrane Laboratory Group of Em.Prof. Joe Diniz da Costa in Chemical Engineering at UQ, where he led inorganic membrane research into hydrogen production, carbon dioxide capture, oxygen production, desalination and membrane reactor technologies. He pioneered metal, metal oxide silica and organosilica membranes, and was amongst the first researchers globally to apply Rapid Thermal Processing (RTP) to inorganic membranes.

Simon has been working with the UQ Dow Centre for Sustainable Engineering Innovation since it’s inception in 2014, where he has focussed on the use of molten metals and molten salts as liquid catalysts for the production of turquoise hydrogen from methane using pyrolysis and CO2 utilisation to produce syngas using dry reforming. He also specialises in broader energy system modelling and decarbonisation pathways, exemplified in projects with the Future Fuels CRC, Net Zero Australia study and GETCO2.

Simon has 147 publications including 9 book chapters and 120 international journal articles at an h-index of 44, with two Highly Cited papers in chemistry and geoscience. He was selected as one of the 2018 Class of Influential Researchers by Industrial & Engineering Chemistry Research. Simon was awarded a Queensland Government Early Career Researcher Fellowship in 2012, and a prestigious UQ Foundation Research Excellence Award for work on 'Low CO2 Iron and Petrochemicals Production' in 2016. Simon was the Secretary for the Membrane Society of Australasia from 2011 - 2013, where he served on the board of directors from 2010 - 2014.

Research Interests:

Simon's research is centred around the sustainable production and use of energy and chemicals - including the development of enabling technologies and processes for the production of clean energy, materials and water. This involves: the design and development of inorganic membranes and hybrid nanocomposite materials for gas and water separation (particularly for carbon capture); the use of molten metals and molten salts as liquid catalysts for low CO2 hydrogen production through methane pyrolysis, CO2 utilisation to produce syngas through dry reforming, and low CO2 iron production via molten iron salts. Simon also specialises in broader energy system modelling and decarbonisation pathways.

Teaching and Learning:

Simon is currently the course coordinator for: Energy Systems, and Sustainable Energy Technologies and Supply Systems. He teaches into Process Systems Analysis.

Availability

Associate Professor Simon Smart is:
Available for supervision

Fields of research

Carbon capture engineering (excl. sequestration) Engineering Separation technologies Water treatment processes

Qualifications

  • Bachelor of Engineering, The University of Queensland
  • Doctor of Philosophy, The University of Queensland

Search Professor Simon Smart’s works on UQ eSpace

160 works between 2006 and 2025
All (160) Journal Article (122) Book Chapter (10) Conference Publication (12) Other Outputs (16)

141 - 160 of 160 works

2011

Book Chapter

Oxygen transport membranes: dense ceramic membranes for power plant applications

Smart, S., Diniz da Costa, J. C., Baumann, S. and Meulenberg, W. A. (2011). Oxygen transport membranes: dense ceramic membranes for power plant applications. Advance membrane science and technology for sustainable energy and environmental applications. (pp. 255-294) edited by Angelo Basile and Suzana Pereira Nunes. Cambridge , United Kingdom: Woodhead Publishing. doi: 10.1533/9780857093790.2.255

Oxygen transport membranes: dense ceramic membranes for power plant applications

2011

Journal Article

Testing of nanostructured gas separation membranes in the flue gas of a post-combustion power plant

Bram, M., Brands, K., Demeusy, T., Zhao, L., Meulenberg, W. A., Pauls, J., Gottlicher, G., Peinemann, KV, Smart, S., Buchkremer, H. P. and Stover, D. (2011). Testing of nanostructured gas separation membranes in the flue gas of a post-combustion power plant. International Journal of Greenhouse Gas Control, 5 (1), 37-48. doi: 10.1016/j.ijggc.2010.08.003

Testing of nanostructured gas separation membranes in the flue gas of a post-combustion power plant

2011

Book Chapter

Inorganic membranes for synthesis gas processing

Smart, S., Ding, L. P. and Diniz da Costa, J. C. (2011). Inorganic membranes for synthesis gas processing. Advanced membrane science and technology for sustainable energy and environmental applications. (pp. 214-254) edited by Angelo Basile and Suzana Pereira Nunes. Cambridge , United Kingdom: Woodhead Publishing. doi: 10.1533/9780857093790.2.214

Inorganic membranes for synthesis gas processing

2010

Journal Article

High temperature steam investigation of cobalt oxide silica membranes for gas separation

Uhlmann, D, Smart, S and Diniz da Costa, JCD (2010). High temperature steam investigation of cobalt oxide silica membranes for gas separation. Separation and Purification Technology, 76 (2), 171-178. doi: 10.1016/j.seppur.2010.10.004

High temperature steam investigation of cobalt oxide silica membranes for gas separation

2010

Journal Article

Long-term flue gas exposure effects of silica membranes on porous steel substrate

Brands, Katharina, Uhlmann, David, Smart, Simon, Bram, Martin and Diniz da Costa, João C. (2010). Long-term flue gas exposure effects of silica membranes on porous steel substrate. Journal of Membrane Science, 359 (1-2), 110-114. doi: 10.1016/j.memsci.2010.02.065

Long-term flue gas exposure effects of silica membranes on porous steel substrate

2010

Journal Article

The effect of carbon nanotube hydrophobicity on the mechanical properties of carbon nanotube-reinforced thermoplastic polyurethane nanocomposites

Smart, Simon, Fania, David, Milev, Adriyan, Kannangara, G. S. Kamali, Lu, Max and Martin, Darren (2010). The effect of carbon nanotube hydrophobicity on the mechanical properties of carbon nanotube-reinforced thermoplastic polyurethane nanocomposites. Journal of Applied Polymer Science, 117 (1), 24-32. doi: 10.1002/app.31115

The effect of carbon nanotube hydrophobicity on the mechanical properties of carbon nanotube-reinforced thermoplastic polyurethane nanocomposites

2010

Journal Article

Assessment of post combustion carbon Capture technologies for power generation

Duke, Mikel C., Ladewig, Bradley, Smart, Simon, Rudolph, Victor and Diniz da Costa, Joao C. (2010). Assessment of post combustion carbon Capture technologies for power generation. Frontiers of Chemical Engineering in China, 4 (2), 184-195. doi: 10.1007/s11705-009-0234-1

Assessment of post combustion carbon Capture technologies for power generation

2010

Book Chapter

Thermoplastic polyurethane nanocomposites

Smart, S. K., Edwards, G. A. and Martin, D. J. (2010). Thermoplastic polyurethane nanocomposites. Rubber nanocomposites: Preparation, properties and applications. (pp. 239-254) edited by Sabu Thomas and Ranimol Stephen. Singapore: John Wiley & Sons. doi: 10.1002/9780470823477.ch10

Thermoplastic polyurethane nanocomposites

2010

Conference Publication

Carbon Templated Silica Membranes for Desalination

Smart, S., Sunarso, J., Lin, C. X. and Diniz da Costa, J. C. (2010). Carbon Templated Silica Membranes for Desalination. 20th Annual Meeting of the North American Membrane Society 2010, NAMS 2010 and 11th International Conference on Inorganic Membranes 2010, ICIM 2010, Washington D.C., USA, 17-22 July 2010. Toledo, Ohio: North American Membrane Society.

Carbon Templated Silica Membranes for Desalination

2010

Conference Publication

Ceramic membrane reactor for the water gas shift reaction: Experiment and modelling

Ding, Li Ping, Smart, Simon and Diniz da Costa, Joao C. (2010). Ceramic membrane reactor for the water gas shift reaction: Experiment and modelling. 6th conference of the Aseanian Membrane Society in conjunction with the 7th International Membrane Science and Technology Conference (AMS6/IMSTEC 10), Sydney , Australia, 22-26 November 2010. Sydney, Australia: University of New South Wales.

Ceramic membrane reactor for the water gas shift reaction: Experiment and modelling

2010

Conference Publication

Improvement in oxygen flux of bscf membranes via yttrium doping

Haworth, P., Smart, S. and Diniz Da Costa, J. C. (2010). Improvement in oxygen flux of bscf membranes via yttrium doping. 20th Annual Meeting of the North American Membrane Society 2010, NAMS 2010 and 11th International Conference on Inorganic Membranes 2010, ICIM 2010, Washington, DC USA, 17-22 July 2010. Toledo, Ohio: North American Membrane Society.

Improvement in oxygen flux of bscf membranes via yttrium doping

2010

Conference Publication

Study of metal oxide nanoparticles in silica membrane materials

Lin, C. X. C., Uhlmann, D., Smart, S. and Diniz da Costa, J. C. (2010). Study of metal oxide nanoparticles in silica membrane materials. IMSTEC 10, Sydney, NSW, Australia, 22 - 25 November 2010.

Study of metal oxide nanoparticles in silica membrane materials

2010

Conference Publication

Design and fabrication of ultra-thin metal-supported oxygen transport membranes

Glasscock, J. A., Kaiser, A., Sogaard, M., Blennow, P., Smart, S., Diniz Da Costa, J. C., Uhlenbruck, S., Baumann, S. and Hendriksen, P. V. (2010). Design and fabrication of ultra-thin metal-supported oxygen transport membranes. 20th Annual Meeting of the North American Membrane Society 2010, NAMS 2010 and 11th International Conference on Inorganic Membranes 2010, ICIM 2010, Washington DC USA, 17-22 July 2010. Toledo, Ohio: North American Membrane Society.

Design and fabrication of ultra-thin metal-supported oxygen transport membranes

2009

Journal Article

Hydrothermal stability of cobalt silica membranes in a water gas shift membrane reactor

Battersby, S., Smart, S., Ladewig, B., Liu, S. M., Duke, M. C., Rudolph, V. and Diniz da Costa, J. C. (2009). Hydrothermal stability of cobalt silica membranes in a water gas shift membrane reactor. SEPARATION AND PURIFICATION TECHNOLOGY, 66 (2), 299-305. doi: 10.1016/j.seppur.2008.12.020

Hydrothermal stability of cobalt silica membranes in a water gas shift membrane reactor

2009

Journal Article

Performance of cobalt silica membranes in gas mixture separation

Battersby, S., Tasaki, T., Smart, S., Ladewig, B., Liu, S. M., Duke, M. C., Rudolph, V. and Diniz da Costa, J. C. D. (2009). Performance of cobalt silica membranes in gas mixture separation. JOURNAL OF MEMBRANE SCIENCE, 329 (1-2), 91-98. doi: 10.1016/j.memsci.2008.12.051

Performance of cobalt silica membranes in gas mixture separation

2009

Conference Publication

Metal silica membrane reactor for hydrogen production from the water gas shift reaction

Tasaki, T., Smart, S. and Diniz da Costa, J. C. (2009). Metal silica membrane reactor for hydrogen production from the water gas shift reaction. AMS-5, Kobe, Japan, 12-14 July 2009. Kobe, Japan: Aseanian Membrane Society.

Metal silica membrane reactor for hydrogen production from the water gas shift reaction

2009

Conference Publication

Carbon capture technologies in enabling clean coal energy delivery

Diniz Da Costa, J. C., Smart, S. and Thambimuthu, K. (2009). Carbon capture technologies in enabling clean coal energy delivery. 20th International Congress of Mechanical Engineering, Gramado, R. S., Brazil, 15-20 November 2009.

Carbon capture technologies in enabling clean coal energy delivery

2008

Journal Article

Novel Nafion composite membranes with mesoporous silica nanospheres as inorganic fillers

Jin, Yonggang, Qiao, Shizhang, Zhang, Lei, Xu, Zhi Ping, Smart, Simon, Diniz da Costa, João C. and Lu, Gao Qing (2008). Novel Nafion composite membranes with mesoporous silica nanospheres as inorganic fillers. Journal of Power Sources, 185 (2), 664-669. doi: 10.1016/j.jpowsour.2008.08.094

Novel Nafion composite membranes with mesoporous silica nanospheres as inorganic fillers

2008

Other Outputs

Carbon nanotube / thermoplastic polyurethane nanocomposites

Smart, Simon Kane (2008). Carbon nanotube / thermoplastic polyurethane nanocomposites. PhD Thesis, School of Engineering, The University of Queensland. doi: 10.14264/155724

Carbon nanotube / thermoplastic polyurethane nanocomposites

2007

Journal Article

Shortened double-walled carbon nanotubes by high-energy ball milling

Smart, S.K., Ren, W.C., Cheng, H.M., Lu, G.Q. and Martin, D.J. (2007). Shortened double-walled carbon nanotubes by high-energy ball milling. International Journal of Nanotechnology, 4 (5), 618-633. doi: 10.1504/IJNT.2007.014756

Shortened double-walled carbon nanotubes by high-energy ball milling

Current funding

  • 2023 - 2030
    ARC Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide
    ARC Centres of Excellence
    Open grant
  • 2022 - 2025
    Advanced chemical recycling of mixed plastics for monomer recovery (ARC Discovery Project administered by Griffith University)
    Griffith University
    Open grant
  • 2021 - 2025
    Net Zero Australia
    Worley Services Pty Limited
    Open grant
  • 2020 - 2025
    A techno-economic assessment of clean energy production from Latrobe Valley brown coal
    Exergen Pty Ltd
    Open grant

Past funding

  • 2023 - 2024
    Decarbonisation Strategic Technology Roadmap
    KPMG
    Open grant
  • 2022 - 2024
    Efficient hydrogen generation via alkaline water electrolysis on low cost electrocatalyst
    HBIS Group Co, Ltd
    Open grant
  • 2021 - 2023
    Net Zero Australia
    Future Fuels CRC Ltd
    Open grant
  • 2021 - 2024
    Efficient conversion of hydrogen into alternative future fuels
    Future Fuels CRC Ltd
    Open grant
  • 2019 - 2024
    Novel technology to produce low-cost blue hydrogen via methane pyrolysis
    Future Fuels CRC Ltd
    Open grant
  • 2019 - 2021
    Dehydrating Coal Seam Gas using Membranes (CRC-P administered by Ezi Fab & Insulation Pty Ltd)
    Ezi Fab & Insulation Pty Ltd
    Open grant
  • 2019 - 2021
    Techno-economic modelling of fuel production processes and supply chains
    Future Fuels CRC Ltd
    Open grant
  • 2019
    Optical Equipment for Advanced Thermofluid Measurements
    UQ Major Equipment and Infrastructure
    Open grant
  • 2018 - 2019
    Supply of Services to develop and deliver the Industry and Resource Sector Adaptation Plan
    Queensland Government Department of Environment and Science
    Open grant
  • 2017 - 2023
    ARC Research Hub for Energy-efficient Separation (ARC Research Hub administered by Monash University)
    Monash University
    Open grant
  • 2017 - 2023
    Mitigation of silica nanoparticle scaling in water treatment
    ARC Linkage Projects
    Open grant
  • 2017
    HCI Regeneration Reactor Testing
    Australian BioRefining Pty Ltd
    Open grant
  • 2015 - 2016
    Self cleaning membranes for tallow recovery from abattoir wastewater
    Australian Meat Processor Corporation
    Open grant
  • 2015 - 2017
    Engineering Models of Permeation in Mixed Matrix Membranes
    ARC Discovery Projects
    Open grant
  • 2012 - 2017
    Carbon Capture Shift Reactors
    Australian National Low Emissions Coal Research and Development
    Open grant
  • 2012 - 2015
    Oxygen membranes for oxyfuel combustion and/or brown and black coal gasification
    Australian National Low Emissions Coal Research and Development
    Open grant
  • 2012 - 2014
    Standards for the scoping & estimating early mover CCS projects
    Australian National Low Emissions Coal Research and Development
    Open grant
  • 2012 - 2016
    Smart Futures Fellowship (Early): Inorganic membranes of coal seam gas water and brine treatment
    Queensland Government Smart Futures Fellowships
    Open grant
  • 2012 - 2013
    A Raman facility for advanced research supporting Australia's natural gas, oil, coal and minerals industries (ARC LIEF Grant administered by UWA)
    ARC LIEF Collaborating/Partner Organisation Contributions
    Open grant
  • 2012 - 2013
    A facility for non-destructive quantification of coal structures, composition and percolation fluid flows in energy and environmental applications
    ARC Linkage Infrastructure, Equipment and Facilities
    Open grant
  • 2012 - 2013
    ResTeach Funding 2012 0.15 FTE School of Chemical Engineering
    UQ ResTeach
    Open grant
  • 2011 - 2014
    Metal oxide silica membrane for hydrogen separation in coal gasification
    CRC for Greenhouse Gas Technologies
    Open grant
  • 2011 - 2013
    High water recovery inland desalination using membrane distillation with ceramic membranes (National Centre for Excellence in Desalination project administered by Murdoch University)
    Murdoch University
    Open grant
  • 2011
    Complete laboratory to semi-industry scale high energy milling and dispersion facility.
    UQ Major Equipment and Infrastructure
    Open grant
  • 2011 - 2013
    Engineered Functional Metal Silica Membranes for Hydrogen Processing
    ARC Discovery Projects
    Open grant
  • 2011 - 2012
    Metal Oxide/Silica Membranes for Desalination
    UQ Early Career Researcher
    Open grant
  • 2011 - 2014
    Non-brittle ceramic hollow fiber membranes
    Monash University
    Open grant
  • 2011 - 2013
    Novel Hybrid Silica Membranes for Desalination
    ARC Discovery Projects
    Open grant
  • 2011
    Polymer gas barrier property facility for development of smart membranes, packing and biomedical films
    UQ Major Equipment and Infrastructure
    Open grant
  • 2011
    ResTeach 2011 0.2 FTE School of Chemical Engineering
    UQ ResTeach
    Open grant

Availability

Associate Professor Simon Smart is:
Available for supervision

Before you email them, read our advice on how to contact a supervisor.

Available projects

  • Perception and uptake of novel CO2 transformation technologies: What can we do with the CO2?

    We seek a student interested in understanding how the public perceives new technologies for transforming carbon dioxide (CO2) into useful products and chemicals. The student will collaborate with experts to:

    • conduct life-cycle and cost-benefit analyses of different CO2 transformation technologies;
    • develop frameworks to consider both the CO2 mitigation potential and/or benefit of products produced from CO2; and
    • develop methodology to integrate circular economy concepts for the fulfillment of sustainable development objectives.
    • In addition, based on surveys and experimental data, the student will also model public perception and technology preferences/choices along the supply chain.

    The student’s earlier training can be in a variety of disciplines but students with a background in: systems thinking, life-cycle assessment, process engineering, and/or an aptitude for applying a variety of quantitative and qualitative methods in industrial ecology are encouraged to apply. Surveys, behavioural experiments, and some econometric tools may be used in parts of the study. There would be opportunities for some methodological skills development as part of the PhD. The student should be willing to work with a team of scholars from engineering, natural and social sciences as well.

    The student will be funded through the Australian Research Council’s Centre of Excellence on Green Electrochemical Transformation of CO2 (GETCO2). Students will be based at The University of Queensland in the School of Chemical Engineering under the principal supervisor of A/Prof Simon Smart. This position will have co-supervision with partner investigator Professor Saleem H. Ali who is based at the Department of Geography and Spatial Sciences at the University of Delaware, USA and there will also be funds available for the student to spend some significant time there.

    The Australian Research Council Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide (GETCO2) gathers a critical mass of expertise to tackle the world’s biggest challenge – carbon dioxide. Led by Professor Xiwang Zhang, GETCO2 is a $45M, 7-year collaboration funded by the ARC, university, industry, and government partners. Our national university partners are The University of Queensland, Griffith University, University of Sydney, University of New South Wales, RMIT, Monash University and University of Adelaide. GETCO2 is the world’s largest research endeavour focusing on electrochemical conversion of CO2 into useful products such as fuels and chemicals. Acting as a focal point for research, training, technology translation and advice, GETCO2 is positioned as a global leader in carbon dioxide transformation. The Centre aims to generate long-term economic, social, and environmental benefits by building capacity and capability to address national and international net-zero obligations. Further information about the Centre can be found at www.getco2.org

  • Perception and uptake of novel CO2 transformation technologies: What can we do with the CO2?

    We seek a student interested in understanding how the public perceives new technologies for transforming carbon dioxide (CO2) into useful products and chemicals. The student will collaborate with experts to:

    • conduct life-cycle and cost-benefit analyses of different CO2 transformation technologies;
    • develop frameworks to consider both the CO2 mitigation potential and/or benefit of products produced from CO2; and
    • develop methodology to integrate circular economy concepts for the fulfillment of sustainable development objectives.
    • In addition, based on surveys and experimental data, the student will also model public perception and technology preferences/choices along the supply chain.

    The student’s earlier training can be in a variety of disciplines but students with a background in: systems thinking, life-cycle assessment, process engineering, and/or an aptitude for applying a variety of quantitative and qualitative methods in industrial ecology are encouraged to apply. Surveys, behavioural experiments, and some econometric tools may be used in parts of the study. There would be opportunities for some methodological skills development as part of the PhD. The student should be willing to work with a team of scholars from engineering, natural and social sciences as well.

    The student will be funded through the Australian Research Council’s Centre of Excellence on Green Electrochemical Transformation of CO2 (GETCO2). Students will be based at The University of Queensland in the School of Chemical Engineering under the principal supervisor of A/Prof Simon Smart. This position will have co-supervision with partner investigator Professor Saleem H. Ali who is based at the Department of Geography and Spatial Sciences at the University of Delaware, USA and there will also be funds available for the student to spend some significant time there.

    The Australian Research Council Centre of Excellence for Green Electrochemical Transformation of Carbon Dioxide (GETCO2) gathers a critical mass of expertise to tackle the world’s biggest challenge – carbon dioxide. Led by Professor Xiwang Zhang, GETCO2 is a $45M, 7-year collaboration funded by the ARC, university, industry, and government partners. Our national university partners are The University of Queensland, Griffith University, University of Sydney, University of New South Wales, RMIT, Monash University and University of Adelaide. GETCO2 is the world’s largest research endeavour focusing on electrochemical conversion of CO2 into useful products such as fuels and chemicals. Acting as a focal point for research, training, technology translation and advice, GETCO2 is positioned as a global leader in carbon dioxide transformation. The Centre aims to generate long-term economic, social, and environmental benefits by building capacity and capability to address national and international net-zero obligations. Further information about the Centre can be found at www.getco2.org

Supervision history

Current supervision

  • Doctor Philosophy

    Investigation and Demonstration at Laboratory Scale, Novel Processes to Produce Near-Zero Carbon Oxide Emissions Hydrogen and Fuels from Methane Through Pyrolysis

    Principal Advisor

    Other advisors: Dr Muxina Konarova

  • Master Philosophy

    Decarbonising the Australian Aviation Industry: with a focus on net-zero emissions

    Principal Advisor

    Other advisors: Dr Saphira Rekker

  • Doctor Philosophy

    Investigation and Demonstration at Laboratory Scale, Novel Processes to Produce Near-Zero Carbon Oxide Emissions Hydrogen and Fuels from Methane Through Pyrolysis

    Principal Advisor

    Other advisors: Dr Muxina Konarova

  • Doctor Philosophy

    Integrating hydrogen from methane pyrolysis into the iron and steel industry

    Principal Advisor

    Other advisors: Dr Travis Mitchell, Dr Christopher Leonardi

  • Doctor Philosophy

    Single-atom catalysts (SACs) as potential catalysts for Electrochemical CO2 reduction

    Associate Advisor

    Other advisors: Professor Tom Rufford

  • Doctor Philosophy

    Production of hydrogen using renewable energy

    Associate Advisor

    Other advisors: Dr Muxina Konarova

  • Doctor Philosophy

    Engineering Mixed-Matrix Membranes (MMMs) for Flue Gas Separation

    Associate Advisor

    Other advisors: Dr Rijia Lin, Dr Gloria Milena Monsalve Bravo

Completed supervision

Enquiries

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