Ms Minh Ho

J01 - Chemical Engineering Building
The University of Sydney

Selected grants

2016

  • Fund to support evaluation and demonstration of high performance CO2 capture membranes; Ho M, Wiley D, Dong G, Li H, Chen V, Ye Y; Department of Primary Industries (NSW)/Coal Innovation NSW Fund.
  • Project 3.1 - CO2 Capture Economics; Ho M; CO2CRC Limited/CRC for Greenhouse Gas Technology.

Selected publications & creative works

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Book Chapters

  • Ho, M., Wiley, D. (2016). Liquid absorbent-based post-combustion CO2 capture in industrial processes. In Paul H.M. Feron (Eds.), Absorption-Based Post-Combustion Capture of Carbon Dioxide, (pp. 711-756). Cambridge: Woodhead Publishing Ltd. [More Information]
  • Wiley, D., Kentish, S., Fimbres Weihs, G., Ho, M., Neal, P. (2014). Well to Wheels Environmental Considerations. In Robert Clark, Mark Thomson (Eds.), Transport Fuels from Australia's Gas Resources: Advancing the nation's energy security, (pp. 162-206). Sydney: University of New South Wales (UNSW) Press.

Journals

  • Turi, D., Ho, M., Ferrari, M., Chiesa, P., Wiley, D., Romano, M. (2017). CO2 capture from natural gas combined cycles by CO2 selective membranes. International Journal of Greenhouse Gas Control, 61, 168-183. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2017). Comparison of Design Options for Encapsulated Solvent Processes for CO2 capture. Energy Procedia, 114, 764-770. [More Information]
  • Ferrara, G., Lanzini, A., Leone, P., Ho, M., Wiley, D. (2017). Exergetic and exergoeconomic analysis of post-combustion CO2 capture using MEA-solvent chemical absorption. Energy, 130, 113-128. [More Information]
  • Ferrarra, G., Ho, M., Lanzini, A., Leone, P., Wiley, D. (2017). Exergetic and Exergoeconomic Analysis of Three Different Technologies for Post-combustion CO2 Capture. Energy Procedia, 114, 6455-6464. [More Information]
  • Neal, P., Ho, M., Fimbres Weihs, G., Wiley, D. (2017). From Building Blocks to Case Studies: Estimating the Costs of Transport and Storage for East Coast Australia. Energy Procedia, 114, 6411-6417. [More Information]
  • Moioli, S., Ho, M., Wiley, D. (2017). Simulation of CO2 Removal by Potassium Taurate Solution. Chemical Engineering Transactions, 57, 1213-1218. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2017). Techno-economic Evaluation of CO2 Capture from Flue Gases Using Encapsulated Solvent. Industrial and Engineering Chemistry Research, 56, 1604-1620. [More Information]
  • Scholes, C., Gosh, U., Ho, M. (2017). The Economics of Helium Separation and Purification by Gas Separation Membranes. Industrial and Engineering Chemistry Research, 56(17), 5014-5020. [More Information]
  • Ho, M., Wiley, D. (2016). Flexible strategies to facilitate carbon capture deployment at pulverised coal power plants. International Journal of Greenhouse Gas Control, 48 Pt 2, 290-299. [More Information]
  • Scholes, C., Ho, M., Wiley, D. (2016). Membrane-Cryogenic Post-Combustion Carbon Capture of Flue Gases from NGCC. Technologies, 14(2), 1-14. [More Information]
  • Khorshidi, Z., Florin, N., Ho, M., Wiley, D. (2016). Techno-economic evaluation of co-firing biomass gas with natural gas in existing NGCC plants with and without CO2 capture. International Journal of Greenhouse Gas Control, 49, 343-363. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2016). Understanding the Impact of Process Design on the Cost of CO2 Capture for Precipitating Solvent Absorption. Industrial and Engineering Chemistry Research, 55(7), 1980-1994. [More Information]
  • Abanades, J., Arias, B., Lyngfelt, A., Mattisson, T., Wiley, D., Li, H., Ho, M., Mangano, E., Brandani, S. (2015). Emerging CO2 capture systems. International Journal of Greenhouse Gas Control, 40, 126-166. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2015). Techno-economic evaluation of using biomass-fired auxiliary units for supplying energy requirements of CO2capture in coal-fired power plants. International Journal of Greenhouse Gas Control, 32, 24-36. [More Information]
  • Pandit, J., Harkin, T., Anderson, C., Ho, M., Wiley, D., Hooper, B. (2014). CO2 emission reduction from natural gas power stations using a precipitating solvent absorption process. International Journal of Greenhouse Gas Control, 28, 234-247. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2014). Energy for CO2 capture: Use of an auxiliary biomass combined heat and power unit. Energy Procedia, 63, 6792-6799. [More Information]
  • Anderson, C., Ho, M., Harkin, T., Wiley, D., Hooper, B. (2014). Large scale economics of a precipitating potassium carbonate CO2 capture process for black coal power generation. Greenhouse Gases: Science and Technology, 4(1), 8-19. [More Information]
  • Scholes, C., Ho, M., Aguiar, A., Wiley, D., Stevens, G., Kentish, S. (2014). Membrane gas separation processes for CO2 capture from cement kiln flue gas. International Journal of Greenhouse Gas Control, 24, 78-86. [More Information]
  • Hou, W., Ho, M., Wiley, D. (2014). Pathways for deploying low-emission technologies in an integrated electricity market: An Australian case study. Energy Procedia, 63, 6864-6870. [More Information]
  • Voleno, A., Romano, M., Turi, D., Chiesa, P., Ho, M., Wiley, D. (2014). Post-combustion CO2 capture from natural gas combined cycles by solvent supported membranes. Energy Procedia, 63, 7389-7397. [More Information]
  • Anderson, C., Hooper, B., Qader, A., Harkin, T., Smith, K., Mumford, K., Pandit, J., Ho, M., Lee, A., Nicholas, N., et al (2014). Recent Developments in the UNO MK 3 Process - A Low Cost, Environmentally Benign Precipitating Process for CO2 Capture. Energy Procedia, 63, 1773-1780. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2014). Reducing the cost of CO2 capture from flue gases using phasechange solvent absorption. Energy Procedia, 63, 2280-2288. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2014). The impact of biomass quality and quantity on the performance and economics of co-firing plants with and without CO2 capture. International Journal of Greenhouse Gas Control, 21, 191-202. [More Information]
  • Ho, M., Bustamante, A., Wiley, D. (2013). Comparison of CO2 capture economics for iron and steel mills. International Journal of Greenhouse Gas Control, 19, 145-159. [More Information]
  • Scholes, C., Ho, M., Wiley, D., Stevens, G., Kentish, S. (2013). Cost competitive membrane-cryogenic post-combustion carbon capture. International Journal of Greenhouse Gas Control, 17, 341-348. [More Information]
  • Zhang, Y., Ho, M., Wiley, D. (2013). Investigating flexible carbon capture opportunities in the Australian electricity market. Energy Procedia, 37, 2746-2753. [More Information]
  • Woods, M., Ho, M., Wiley, D. (2013). Pathways for deploying CCS at Australian power plants. Energy Procedia, 37, 2602-2610. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2013). Reducing the Cost of CO2 Capture from Flue Gases Using Aqueous Chemical Absorption. Industrial and Engineering Chemistry Research, 52(47), 16887-16901. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2013). Techno-economic study of biomass co-firing with and without CO2 capture in an Australian black coal-fired power plant. Energy Procedia, 37, 6035-6042. [More Information]
  • Wiley, D., Ho, M., Bustamente, A. (2011). Assessment of opportunities for CO 2 capture at iron and steel mills: An Australian perspective. Energy Procedia, 4, 2654-2661. [More Information]
  • Ho, M., Allinson, G., Wiley, D. (2011). Comparison of MEA capture cost for low CO2 emissions sources in Australia. International Journal of Greenhouse Gas Control, 5(1), 49-60. [More Information]
  • Fimbres Weihs, G., Wiley, D., Ho, M. (2011). Steady-state optimisation of CCS pipeline networks for cases with multiple emission sources and injection sites: South-east Queensland case study. Energy Procedia, 4, 2748-2755. [More Information]
  • Wiley, D., Ho, M., Donde, L. (2011). Technical and economic opportunities for flexible CO 2 capture at Australian black coal fired power plants. Energy Procedia, 4, 1893-1900. [More Information]
  • Ho, M., Allinson, G., Wiley, D. (2009). Factors affecting the cost of capture for Australian lignite coal fired power plants. Energy Procedia, 1(1), 763-770. [More Information]

Research Reports

  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 10: Carbon Dioxide Transport and Storage, (pp. 179 - 201). Melbourne, Australia: Electric Power Research Institute.
  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 20: CO2 Transport and Storage Case Studies, (pp. 277 - 292). Melbourne, Australia: Electric Power Research Institute.
  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 21: CO2 Transport and Storage - Additional Datasets, (pp. 293 - 325). Melbourne, Australia: Electric Power Research Institute.

2017

  • Turi, D., Ho, M., Ferrari, M., Chiesa, P., Wiley, D., Romano, M. (2017). CO2 capture from natural gas combined cycles by CO2 selective membranes. International Journal of Greenhouse Gas Control, 61, 168-183. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2017). Comparison of Design Options for Encapsulated Solvent Processes for CO2 capture. Energy Procedia, 114, 764-770. [More Information]
  • Ferrara, G., Lanzini, A., Leone, P., Ho, M., Wiley, D. (2017). Exergetic and exergoeconomic analysis of post-combustion CO2 capture using MEA-solvent chemical absorption. Energy, 130, 113-128. [More Information]
  • Ferrarra, G., Ho, M., Lanzini, A., Leone, P., Wiley, D. (2017). Exergetic and Exergoeconomic Analysis of Three Different Technologies for Post-combustion CO2 Capture. Energy Procedia, 114, 6455-6464. [More Information]
  • Neal, P., Ho, M., Fimbres Weihs, G., Wiley, D. (2017). From Building Blocks to Case Studies: Estimating the Costs of Transport and Storage for East Coast Australia. Energy Procedia, 114, 6411-6417. [More Information]
  • Moioli, S., Ho, M., Wiley, D. (2017). Simulation of CO2 Removal by Potassium Taurate Solution. Chemical Engineering Transactions, 57, 1213-1218. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2017). Techno-economic Evaluation of CO2 Capture from Flue Gases Using Encapsulated Solvent. Industrial and Engineering Chemistry Research, 56, 1604-1620. [More Information]
  • Scholes, C., Gosh, U., Ho, M. (2017). The Economics of Helium Separation and Purification by Gas Separation Membranes. Industrial and Engineering Chemistry Research, 56(17), 5014-5020. [More Information]

2016

  • Ho, M., Wiley, D. (2016). Flexible strategies to facilitate carbon capture deployment at pulverised coal power plants. International Journal of Greenhouse Gas Control, 48 Pt 2, 290-299. [More Information]
  • Ho, M., Wiley, D. (2016). Liquid absorbent-based post-combustion CO2 capture in industrial processes. In Paul H.M. Feron (Eds.), Absorption-Based Post-Combustion Capture of Carbon Dioxide, (pp. 711-756). Cambridge: Woodhead Publishing Ltd. [More Information]
  • Scholes, C., Ho, M., Wiley, D. (2016). Membrane-Cryogenic Post-Combustion Carbon Capture of Flue Gases from NGCC. Technologies, 14(2), 1-14. [More Information]
  • Khorshidi, Z., Florin, N., Ho, M., Wiley, D. (2016). Techno-economic evaluation of co-firing biomass gas with natural gas in existing NGCC plants with and without CO2 capture. International Journal of Greenhouse Gas Control, 49, 343-363. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2016). Understanding the Impact of Process Design on the Cost of CO2 Capture for Precipitating Solvent Absorption. Industrial and Engineering Chemistry Research, 55(7), 1980-1994. [More Information]

2015

  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 10: Carbon Dioxide Transport and Storage, (pp. 179 - 201). Melbourne, Australia: Electric Power Research Institute.
  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 20: CO2 Transport and Storage Case Studies, (pp. 277 - 292). Melbourne, Australia: Electric Power Research Institute.
  • Wiley, D., Neal, P., Ho, M., Fimbres Weihs, G. (2015). Australian Power Generation Technology Report | 21: CO2 Transport and Storage - Additional Datasets, (pp. 293 - 325). Melbourne, Australia: Electric Power Research Institute.
  • Abanades, J., Arias, B., Lyngfelt, A., Mattisson, T., Wiley, D., Li, H., Ho, M., Mangano, E., Brandani, S. (2015). Emerging CO2 capture systems. International Journal of Greenhouse Gas Control, 40, 126-166. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2015). Techno-economic evaluation of using biomass-fired auxiliary units for supplying energy requirements of CO2capture in coal-fired power plants. International Journal of Greenhouse Gas Control, 32, 24-36. [More Information]

2014

  • Pandit, J., Harkin, T., Anderson, C., Ho, M., Wiley, D., Hooper, B. (2014). CO2 emission reduction from natural gas power stations using a precipitating solvent absorption process. International Journal of Greenhouse Gas Control, 28, 234-247. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2014). Energy for CO2 capture: Use of an auxiliary biomass combined heat and power unit. Energy Procedia, 63, 6792-6799. [More Information]
  • Anderson, C., Ho, M., Harkin, T., Wiley, D., Hooper, B. (2014). Large scale economics of a precipitating potassium carbonate CO2 capture process for black coal power generation. Greenhouse Gases: Science and Technology, 4(1), 8-19. [More Information]
  • Scholes, C., Ho, M., Aguiar, A., Wiley, D., Stevens, G., Kentish, S. (2014). Membrane gas separation processes for CO2 capture from cement kiln flue gas. International Journal of Greenhouse Gas Control, 24, 78-86. [More Information]
  • Hou, W., Ho, M., Wiley, D. (2014). Pathways for deploying low-emission technologies in an integrated electricity market: An Australian case study. Energy Procedia, 63, 6864-6870. [More Information]
  • Voleno, A., Romano, M., Turi, D., Chiesa, P., Ho, M., Wiley, D. (2014). Post-combustion CO2 capture from natural gas combined cycles by solvent supported membranes. Energy Procedia, 63, 7389-7397. [More Information]
  • Anderson, C., Hooper, B., Qader, A., Harkin, T., Smith, K., Mumford, K., Pandit, J., Ho, M., Lee, A., Nicholas, N., et al (2014). Recent Developments in the UNO MK 3 Process - A Low Cost, Environmentally Benign Precipitating Process for CO2 Capture. Energy Procedia, 63, 1773-1780. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2014). Reducing the cost of CO2 capture from flue gases using phasechange solvent absorption. Energy Procedia, 63, 2280-2288. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2014). The impact of biomass quality and quantity on the performance and economics of co-firing plants with and without CO2 capture. International Journal of Greenhouse Gas Control, 21, 191-202. [More Information]
  • Wiley, D., Kentish, S., Fimbres Weihs, G., Ho, M., Neal, P. (2014). Well to Wheels Environmental Considerations. In Robert Clark, Mark Thomson (Eds.), Transport Fuels from Australia's Gas Resources: Advancing the nation's energy security, (pp. 162-206). Sydney: University of New South Wales (UNSW) Press.

2013

  • Ho, M., Bustamante, A., Wiley, D. (2013). Comparison of CO2 capture economics for iron and steel mills. International Journal of Greenhouse Gas Control, 19, 145-159. [More Information]
  • Scholes, C., Ho, M., Wiley, D., Stevens, G., Kentish, S. (2013). Cost competitive membrane-cryogenic post-combustion carbon capture. International Journal of Greenhouse Gas Control, 17, 341-348. [More Information]
  • Zhang, Y., Ho, M., Wiley, D. (2013). Investigating flexible carbon capture opportunities in the Australian electricity market. Energy Procedia, 37, 2746-2753. [More Information]
  • Woods, M., Ho, M., Wiley, D. (2013). Pathways for deploying CCS at Australian power plants. Energy Procedia, 37, 2602-2610. [More Information]
  • Raksajati, A., Ho, M., Wiley, D. (2013). Reducing the Cost of CO2 Capture from Flue Gases Using Aqueous Chemical Absorption. Industrial and Engineering Chemistry Research, 52(47), 16887-16901. [More Information]
  • Khorshidi, Z., Ho, M., Wiley, D. (2013). Techno-economic study of biomass co-firing with and without CO2 capture in an Australian black coal-fired power plant. Energy Procedia, 37, 6035-6042. [More Information]

2011

  • Wiley, D., Ho, M., Bustamente, A. (2011). Assessment of opportunities for CO 2 capture at iron and steel mills: An Australian perspective. Energy Procedia, 4, 2654-2661. [More Information]
  • Ho, M., Allinson, G., Wiley, D. (2011). Comparison of MEA capture cost for low CO2 emissions sources in Australia. International Journal of Greenhouse Gas Control, 5(1), 49-60. [More Information]
  • Fimbres Weihs, G., Wiley, D., Ho, M. (2011). Steady-state optimisation of CCS pipeline networks for cases with multiple emission sources and injection sites: South-east Queensland case study. Energy Procedia, 4, 2748-2755. [More Information]
  • Wiley, D., Ho, M., Donde, L. (2011). Technical and economic opportunities for flexible CO 2 capture at Australian black coal fired power plants. Energy Procedia, 4, 1893-1900. [More Information]

2009

  • Ho, M., Allinson, G., Wiley, D. (2009). Factors affecting the cost of capture for Australian lignite coal fired power plants. Energy Procedia, 1(1), 763-770. [More Information]

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