Overview
Background
Dr. Anthony Halog: A Pioneer in Sustainable Systems and Circular Economy
Dr. Anthony Halog is a leading authority in sustainable systems engineering and circular economy, with over 22 years of post-PhD experience in academia and research. His work focuses on integrating life cycle assessment (LCA), systems thinking, and industrial ecology to advance global sustainability efforts. Dr. Halog has successfully led numerous research projects in industrial ecology and sustainable supply chain management, contributing significantly to the United Nations Sustainable Development Goals (UNSDGs) and Planetary Boundaries frameworks.
His prolific career includes over 125 publications that have been widely cited and referenced in policy documents by international bodies such as the United Nations and the European Union. With a strong commitment to mentoring, Dr. Halog has guided numerous PhD candidates and postdoctoral researchers, fostering the next generation of sustainability experts. Since completing his PhD, he has examined numerous theses from various universities in Australia, North America, Africa, and Asia. His experience also extends to reviewing several grant proposals for prestigious funding bodies, including the National Science Foundation in the USA and European funding schemes.
Dr. Anthony Halog has received numerous fellowships and awards throughout his career. Notably, he was awarded fellowships from prestigious institutions such as the OECD, DAAD, and the Japan Society for the Promotion of Science (JSPS). He has held visiting fellowships across the globe, including in the UK, Germany, Japan, and Saudi Arabia, focusing on areas like Circular Economy, Green Hydrogen Policy, and Life Cycle Assessment. Dr. Halog's accolades also include early career fellowships from NSERC (Canada) and JSPS, along with several international research grants and academic scholarships, reflecting his global recognition in sustainability science and engineering.
Key areas of expertise include circular economy, bioeconomy, LCA, sustainable supply chain management, and the application of operations research and optimization in engineering sustainable systems. Dr. Halog’s interdisciplinary approach and international collaborations have positioned him as a thought leader in transitioning to a low-carbon, circular economy.
Availability
- Dr Anthony Halog is:
- Available for supervision
- Media expert
Fields of research
Qualifications
- Bachelor of Science, University of Mindanao
- Masters (Research) of Engineering, unknown
- Masters (Coursework) of Business Administration (Advanced), Monash University
- Doctoral Diploma, Karlsruher Institut für Technologie
Research interests
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AI/Digitalisation-Enabled Circular Bioeconomy
This research project aims to leverage digitalization, AI, and data analytics to advance the circular bioeconomy by optimizing the conversion of sustainable biomass into high-value bioproducts. Using life cycle sustainability assessment (LCSA) and systems modeling, the project will enhance resource efficiency, reduce environmental impact, and support the transition to a circular economy. Key outcomes include scalable solutions for sustainable production systems and policy recommendations for bioeconomy advancement.
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Transitions to Energy Sustainability
This research project focuses on advancing energy sustainability through the integration of digitalisation, artificial intelligence (AI), data science, and analytics methods. The aim is to develop innovative solutions that enhance the efficiency and sustainability of energy systems. By leveraging AI and data-driven approaches, this project will explore the optimization of renewable energy integration, predictive maintenance, and energy consumption patterns, contributing to a resilient, low-carbon energy future.
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Corporate Environmental Management for Sustainable and ESG Business Practices
This research project on Corporate Environmental Management aims to leverage digitalisation, AI, data science, and analytics to advance sustainable business practices aligned with ESG frameworks. By integrating cutting-edge technologies, the project will develop predictive models and decision-support systems to optimise resource efficiency, reduce carbon footprints, and enhance circular economy strategies. The project seeks to create scalable solutions that drive sustainability in corporate operations, making significant contributions to both academic research and industry practices.
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AI/Data Science-Enabled Circular Economy
Leveraging digitalization, AI, and data analytics, this research explores innovative pathways for advancing a circular economy. By integrating these technologies, the project aims to optimize resource efficiency, minimize waste, and close material and energy loops, supporting sustainable production and consumption. The focus is on developing data-driven strategies to enhance circularity across industries, contributing to global sustainability and achieving economic resilience through cutting-edge, circular business models.
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Digitalisation-Enabled Industrial Ecology
Leveraging digitalisation, AI, and data science, this project in Industrial Ecology aims to innovate sustainable industrial systems by analyzing material and energy flows. It focuses on transforming linear production processes into circular, low-carbon models, enhancing resource efficiency and minimizing waste. The research integrates life cycle assessment, circular economy principles, and advanced computational methods to develop scalable solutions for sustainable production and consumption systems, aligning with global sustainability goals.
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Environmental systems modelling and analysis
This research focuses on environmental systems modeling and analysis, leveraging digitalization, AI, and data science to optimize sustainability outcomes. By integrating tools such as Life Cycle Assessment (LCA) and Material Flow Analysis (MFA), the project aims to address complex environmental challenges in circular bioeconomy, renewable energy, and resource management. This innovative approach supports decision-making for sustainable development and enhances the environmental performance of industrial systems.
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AI-enabled Green Economy
This research investigates the integration of digitalization, AI, and data science to drive a just transition to a low-carbon, resource-efficient, and socially inclusive green economy. By analyzing the socio-environmental-economic impacts of converting sustainable feedstocks and waste into bioproducts, this work aims to enhance circular bioeconomy practices, improve resource efficiency, and reduce ecological footprints in line with sustainable development goals.
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Data Analytics-Supported Green Supply Chain Management
This research project on Data Analytics-Supported Green Supply Chain Management leverages digitalisation, AI, data science, and analytics methods to optimise supply chains for sustainability. The project aims to reduce carbon footprints, enhance resource efficiency, and promote circular economy practices by integrating advanced data analytics with life cycle assessment (LCA) and systems thinking. The innovative approach targets key sustainability goals, making a significant impact on environmental performance and supply chain resilience.
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Techno-Economic Analysis and Life Cycle Analysis
This project focuses on advancing Techno-Economic Analysis (TEA) and Life Cycle Analysis (LCA) by leveraging digitalization, Artificial Intelligence (AI), data science, and analytics. It aims to optimize sustainable energy systems and circular economy processes, integrating environmental, economic, and social impacts. The project will develop innovative, data-driven models to enhance decision-making in bioeconomy, renewable energy, and waste valorization industries, contributing to a low-carbon, circular economy and sustainable development goals (SDGs).
Research impacts
Dr. Anthony Halog's research has made a significant impact beyond academia, driving sustainability in various sectors and influencing policy at global levels. His work on life cycle assessment (LCA) and circular economy strategies has directly contributed to reducing environmental footprints in industries such as energy, waste management, and bioeconomy.
One of the most notable outcomes of Dr. Halog’s research is the application of LCA to optimize waste management systems, particularly in transitioning to a circular economy. His studies have been instrumental in shaping waste-to-energy policies in Indonesia and bioenergy strategies across the ASEAN region. These contributions have led to the development of sustainable practices that reduce greenhouse gas emissions and enhance resource efficiency.
Dr. Halog’s research has also been pivotal in advancing the understanding of sustainable supply chains, helping businesses minimize their environmental impact while maintaining economic viability. His interdisciplinary approach, combining systems thinking with practical applications, has empowered industries to adopt more sustainable practices, ultimately benefiting society by fostering a healthier environment and promoting economic resilience.
Through his extensive publications and collaborations, Dr. Halog’s work continues to influence sustainability policies and practices globally, making a lasting impact on both the economy and the environment.
Works
Search Professor Anthony Halog’s works on UQ eSpace
Featured
2024
Journal Article
The Necessity for End-of-Life Photovoltaic Technology Waste Management Policy: A Systematic Review
Hei, Kwok Ka, Savaget, Paulo, Fukushige, Shinichi and Halog, Anthony (2024). The Necessity for End-of-Life Photovoltaic Technology Waste Management Policy: A Systematic Review. Journal of Cleaner Production, 461 142497, 142497. doi: 10.1016/j.jclepro.2024.142497
Featured
2024
Book Chapter
Waste management sector’s contribution to meeting sustainable development goals: a social life cycle assessment approach
Celeste, Novlloyd E. and Halog, Anthony B. (2024). Waste management sector’s contribution to meeting sustainable development goals: a social life cycle assessment approach. Waste management in the circular economy. (pp. 189-206) edited by Suhaib A. Bandh and Fayaz A. Malla. Cham, Switzerland: Springer Cham. doi: 10.1007/978-3-031-42426-7_10
Featured
2022
Journal Article
How to advance regional circular bioeconomy systems? Identifying barriers, challenges, drivers, and opportunities
Salvador, Rodrigo, Barros, Murillo Vetroni, Donner, Mechthild, Brito, Paulo, Halog, Anthony and De Francisco, Antonio C. (2022). How to advance regional circular bioeconomy systems? Identifying barriers, challenges, drivers, and opportunities. Sustainable Production and Consumption, 32, 248-269. doi: 10.1016/j.spc.2022.04.025
Featured
2022
Journal Article
Energy-economic-environmental cycle evaluation comparing two polyethylene and polycarbonate plastic greenhouses in cucumber production (from production to packaging and distribution)
Hesampour, Reza, Taki, Morteza, Fathi, Rostam, Hassani, Mehrdad and Halog, Anthony (2022). Energy-economic-environmental cycle evaluation comparing two polyethylene and polycarbonate plastic greenhouses in cucumber production (from production to packaging and distribution). Science of the Total Environment, 828 154232, 154232. doi: 10.1016/j.scitotenv.2022.154232
Featured
2022
Book Chapter
Biofuel economy, development, and food security
Varela, Rowena P., Balanay, Raquel M., Capangpangan, Rey Y. and Halog, Anthony B. (2022). Biofuel economy, development, and food security. Biofuels in circular economy. (pp. 17-30) edited by Suhaib A. Bandh and Fayaz A. Malla. Singapore: Springer Nature Singapore. doi: 10.1007/978-981-19-5837-3_2
Featured
2021
Journal Article
A unique perspective of materials, practices and structures within the food, energy and water nexus of Australian urban alternative food networks
Cronin, Ryan and Halog, Anthony (2021). A unique perspective of materials, practices and structures within the food, energy and water nexus of Australian urban alternative food networks. Circular Economy and Sustainability, 2 (1), 327-349. doi: 10.1007/s43615-021-00110-4
Featured
2021
Journal Article
A review of reductionist versus systems perspectives towards ‘doing the right strategies right’ for circular economy implementation
Balanay, Raquel and Halog, Anthony (2021). A review of reductionist versus systems perspectives towards ‘doing the right strategies right’ for circular economy implementation. Systems, 9 (2) 38, 38. doi: 10.3390/systems9020038
Featured
2021
Journal Article
Circular economy strategies on business modelling: identifying the greatest influences
Salvador, Rodrigo, Barros, Murillo V., Freire, Fausto, Halog, Anthony, Piekarski, Cassiano M. and De Francisco, Antonio C. (2021). Circular economy strategies on business modelling: identifying the greatest influences. Journal of Cleaner Production, 299 126918, 126918. doi: 10.1016/j.jclepro.2021.126918
Featured
2021
Journal Article
Circular economy across Australia: Taking stock of progress and lessons
Halog, Anthony, Balanay, Raquel, Anieke, Sandra and Yu, Tsz Yan (2021). Circular economy across Australia: Taking stock of progress and lessons. Circular Economy and Sustainability, 1 (1), 283-301. doi: 10.1007/s43615-021-00020-5
Featured
2021
Journal Article
A review of circular economy studies in developed countries and its potential adoption in developing countries
Halog, Anthony and Anieke, Sandra (2021). A review of circular economy studies in developed countries and its potential adoption in developing countries. Circular Economy and Sustainability, 1 (1), 209-230. doi: 10.1007/s43615-021-00017-0
Featured
2021
Book Chapter
Evaluating the sustainability of feedlot production in Australia using a life cycle sustainability assessment framework
Pagotto, Murilo, Halog, Anthony, Costa, Diogo Fleury Azevedo and Lu, Tianchu (2021). Evaluating the sustainability of feedlot production in Australia using a life cycle sustainability assessment framework. Life Cycle Sustainability Assessment (LCSA). (pp. 137-178) edited by Subramanian Senthilkannan Muthu. Singapore: Springer. doi: 10.1007/978-981-16-4562-4_7
Featured
2020
Journal Article
Towards better life cycle assessment and circular economy: on recent studies on interrelationships among environmental sustainability, food systems and diet
Lu, Tianchu and Halog, Anthony (2020). Towards better life cycle assessment and circular economy: on recent studies on interrelationships among environmental sustainability, food systems and diet. International Journal of Sustainable Development and World Ecology, 27 (6), 1-9. doi: 10.1080/13504509.2020.1734984
Featured
2019
Journal Article
Renewable energy projections for climate change mitigation: an analysis of uncertainty and errors
al Irsyad, Muhammad Indra, Halog, Anthony and Nepal, Rabindra (2019). Renewable energy projections for climate change mitigation: an analysis of uncertainty and errors. Renewable Energy, 130, 536-546. doi: 10.1016/j.renene.2018.06.082
Featured
2017
Journal Article
Renewable energy projections for climate change migration: an analysis of uncertainty and errors
Irsyad, M. Indra al, Halog, Anthony and Nepal, Rabindra (2017). Renewable energy projections for climate change migration: an analysis of uncertainty and errors. CAMA working paper series. 74/2017. Centre for Applied Macroeconomic Analysis.
Featured
2016
Journal Article
Exploring the potential of participatory systems thinking techniques in progressing SLCA
McCabe, Annie and Halog, Anthony (2016). Exploring the potential of participatory systems thinking techniques in progressing SLCA. International Journal of Life Cycle Assessment, 23 (3), 1-12. doi: 10.1007/s11367-016-1143-4
Featured
2016
Journal Article
Developing strategies for managing construction and demolition wastes in Malaysia based on the concept of circular economy
Esa, Mohd Reza, Halog, Anthony and Rigamonti, Lucia (2016). Developing strategies for managing construction and demolition wastes in Malaysia based on the concept of circular economy. Journal of Material Cycles and Waste Management, 18 (3), 1-11. doi: 10.1007/s10163-016-0516-x
Featured
2016
Journal Article
Promoting life cycle thinking for sustainability in the mining sector of the Philippines
Balanay, Raquel M. and Halog, Anthony (2016). Promoting life cycle thinking for sustainability in the mining sector of the Philippines. International Journal of Life Cycle Assessment, 22 (11), 1-11. doi: 10.1007/s11367-016-1105-x
Featured
2016
Book Chapter
Evaluating supply chain networks by incorporating the triple dimensions of sustainability paradigm
Halog, Anthony and Nguyen, Nga H. (2016). Evaluating supply chain networks by incorporating the triple dimensions of sustainability paradigm. Implementing triple bottom line sustainability into global supply chains. (pp. 165-186) edited by Lydia Bals and Wendy L. Tate. Sheffield, United Kingdom: Greenleaf Publishing. doi: 10.4324/9781351285124
Featured
2016
Book Chapter
Life Cycle Sustainability Assessments
Halog, Anthony and Manik, Yosef (2016). Life Cycle Sustainability Assessments. Encyclopedia of Inorganic and Bioinorganic Chemistry. (pp. 1-17) edited by Robert A. Scott. Hoboken, NJ, United States: John Wiley & Sons. doi: 10.1002/9781119951438.eibc2372
Featured
2015
Journal Article
Environmental life cycle assessments of emerging anode materials for Li-ion batteries-metal oxide NPs
Padashbarmchi, Zahra, Hamidian, Amir Hossein, Khorasani, Nematolah, Kazemzad, Mahmood, McCabe, Annie and Halog, Anthony (2015). Environmental life cycle assessments of emerging anode materials for Li-ion batteries-metal oxide NPs. Environmental Progress and Sustainable Energy, 34 (6), 1740-1747. doi: 10.1002/ep.12148
Funding
Past funding
Supervision
Availability
- Dr Anthony Halog is:
- Available for supervision
Before you email them, read our advice on how to contact a supervisor.
Available projects
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Circular Economy and Resource Governance: Transition to Circular Agriculture and Bioeconomy in Australia
This research project explores the transition to circular agriculture and bioeconomy in Australia, focusing on sustainable phosphate utilization for fertilizer production. By integrating life cycle and systems engineering approaches, the project aims to optimize resource management, reduce environmental impacts, and support sustainable development. The research aligns with Australia's national priorities, contributing to innovative strategies for environmental conservation, waste management, and sustainable agricultural practices.
-
Dynamic System Modelling of Relationships between Environmental Sustainability, Food and Health Issues
This project aims to develop a cutting-edge computational model to explore the complex interrelationships between sustainability, climate change, food systems, dietary choices, and human health. Utilizing system dynamics and agent-based modeling (ABM), alongside AI, data science, and digitalization, the project will enable scenario analysis and policy formulation. The focus is on creating sustainable solutions, with an emphasis on developing expertise in modeling, data management, and innovative analytics for dynamic system analysis.
-
Life Cycle Sustainability Analysis of Deployment of Renewable Energy technologies
This project critically evaluates the environmental and socio-economic impacts of large-scale renewable energy deployment, focusing on green hydrogen, hydro and bioenergy. Utilizing advanced life cycle assessment (LCA), system dynamics, and data science, it identifies key impact "hot spots" across the energy lifecycle. The project aims to develop strategic frameworks for sustainable renewable energy adoption, leveraging digitalization, AI, and analytics to optimize resource efficiency and minimize trade-offs in renewable energy systems.
-
Systems Modelling of Linked Circular Economies
This project innovatively integrates System Dynamics Modelling (SDM) to analyze the urban food-energy-water nexus, aiming to minimize waste by explicitly linking circular economies. By leveraging digitalization, AI, and data science, the project visualizes resource pathways, identifies inefficiencies, and proposes sustainable solutions. This approach enhances urban resource management, reduces waste, and addresses critical sustainability challenges, making it highly relevant to experts in circular economy and sustainable urban development.
-
Integrated Assessment Modelling
This innovative research project integrates Industrial Ecology methods, including Life Cycle Assessment (LCA), Material Flow Analysis (MFA), and Input-Output Analysis (IOA), with Integrated Assessment Modelling (IAM) to explore low-carbon transition pathways. Utilizing the open-source MESSAGEix framework, the project will assess climate change mitigation and circular economy impacts in energy, transport, and materials sectors. Leveraging AI, digitalization, and data science, this framework aims to guide sustainable energy transitions and circular economy strategies.
-
Material Flow Accounting and Input-output Analysis for Reducing Energy Demand
This research project aims to reduce energy demand by transforming material and product consumption patterns across the supply chain. By integrating a hybrid model combining monetary-based input-output, physical, and energy data, the project will analyze historical consumption drivers over 20 years. Utilizing digitalization, AI, and data science, the project will inform sustainable consumption and production policies, contributing to climate action and enhancing resource efficiency across Australia's economy.
-
Dynamic System Modelling and Analysis for Pursuing Sustainable Bioeconomy
This project aims to develop a cutting-edge, spatially and temporally explicit systems model for sustainable aviation fuel production in Australia using bioenergy feedstocks such as microalgae, pongamia pinnata, and sugarcane. By integrating digitalization, AI, and data science, the model will assess carbon and water footprints, human health impacts, and economic viability. The project will address uncertainties and optimize bioenergy pathways, contributing to Australia's low-carbon energy future.
-
Socio-Economic and Ethical Implications of Scaling Up Green Hydrogen Production in Australia
This research explores the socio-economic and ethical challenges of scaling up green hydrogen production in Australia, crucial for achieving net-zero emissions. By analyzing current technologies, environmental impacts, and public perceptions, the study aims to develop strategies for equitable and sustainable hydrogen adoption. It integrates quantitative and qualitative methods to assess technical viability, justice issues, and stakeholder engagement, providing insights to guide policy development and promote a socially just energy transition.
-
Integration of Multi Agent Systems (MAS) and LCA for Analysing Australian Agri-food Sector
This project aims to develop a practical and comprehensive methodology for the integration of Multi Agent Systems (MAS) and life cycle assessment (LCA). In order to identify and characterize the Australian agro-system, this project will develop a prototype computational model to simulate Australian agricultural sector. Preferably, applicant has background in computer science or applied mathematics with experience in agent-based systems as well as strong interest in computation, applied mathematics, optimization and scientific programming. Successful applicant will develop skills in modelling, analysis, data management, scenario and policy formulation and the development of sustainable solutions.
-
Pursuing Circular Agriculture and Bioeconomy for Sustainable Industrial Development
This research project aims to transform agri-food systems from linear production to a circular economy by developing a comprehensive database and applying advanced life cycle and systems-based methods. The project will assess biodiversity, land use, water, and phosphorus impacts across selected food sub-sectors. Leveraging digitalization, AI, and data analytics, it will propose circular economy models for sustainable consumption and production, ensuring resilience and environmental efficiency in Australian agriculture.
-
Modelling Urban Metabolism of Cities
This research project aims to develop a holistic multi-agent-based framework to model complex urban systems like Brisbane and assess their sustainability. Leveraging digitalization, AI, data science, and analytics, the project will create a roadmap for sustainable urban development. Through comprehensive literature review, survey development, and statistical analysis, it will provide innovative solutions for urban planners and policymakers to address resource pressure, ecosystem degradation, and sustainable city growth. Keywords: sustainable urban development, multi-agent systems, AI, digitalization, urban sustainability, data science.
-
Agent-Based Modelling of Linked Circular Economies
This project explores innovative waste reduction in urban food-energy-water (FEW) nexus by integrating circular economies through Agent-Based Modeling (ABM). By simulating stakeholder decision-making, the project analyzes resource fluxes as emergent properties, identifying synergies, feedbacks, and thresholds within the FEW nexus. Leveraging digitalization, AI, and data science, the project aims to optimize urban resource management, enhancing sustainability by reducing inefficiencies and minimizing waste across interconnected systems.
-
Stocks and Flows of Metals and Mineral Resources: Quantifying Environmental Impacts and Risks
This research project explores the metal and mineral resource needs of Japanese and Korean industries, with a focus on rare earth metals and other resources supplied by Australia's mining sector. It will develop a comprehensive database to quantify resource usage and propose circular economy models for Queensland’s mining industry, leveraging digitalization, AI, and systems thinking. The project aims to align resource extraction with ecological limits while meeting international demands sustainably.
-
Digitalisation-Enabled Circular Bioeconomy for Global Transformation
This project aims to develop a digitalisation-enabled circular bioeconomy framework, focusing on the integration of advanced digital technologies with circular bioeconomy principles. The research will explore how digital tools such as AI and blockchain can enhance the sustainability of bioeconomic practices, particularly in agricultural value chains. This project will address challenges in environmental valuation, public acceptance of innovative technologies, and governance of sustainable value chains. The outcomes will contribute to policy recommendations and innovative models for the circular bioeconomy, supporting the global sustainability and digitalisation goals.
-
Dynamic System Modelling of Relationships between Environmental Sustainability, Food and Health Issues
This project aims to develop a cutting-edge computational model to explore the complex interrelationships between sustainability, climate change, food systems, dietary choices, and human health. Utilizing system dynamics and agent-based modeling (ABM), alongside AI, data science, and digitalization, the project will enable scenario analysis and policy formulation. The focus is on creating sustainable solutions, with an emphasis on developing expertise in modeling, data management, and innovative analytics for dynamic system analysis.
-
Life Cycle Sustainability Analysis of Deployment of Renewable Energy technologies
This project critically evaluates the environmental and socio-economic impacts of large-scale renewable energy deployment, focusing on green hydrogen, hydro and bioenergy. Utilizing advanced life cycle assessment (LCA), system dynamics, and data science, it identifies key impact "hot spots" across the energy lifecycle. The project aims to develop strategic frameworks for sustainable renewable energy adoption, leveraging digitalization, AI, and analytics to optimize resource efficiency and minimize trade-offs in renewable energy systems.
-
Systems Modelling of Linked Circular Economies
This project innovatively integrates System Dynamics Modelling (SDM) to analyze the urban food-energy-water nexus, aiming to minimize waste by explicitly linking circular economies. By leveraging digitalization, AI, and data science, the project visualizes resource pathways, identifies inefficiencies, and proposes sustainable solutions. This approach enhances urban resource management, reduces waste, and addresses critical sustainability challenges, making it highly relevant to experts in circular economy and sustainable urban development.
-
Circular Economy and Resource Governance: Transition to Circular Agriculture and Bioeconomy in Australia
This research project explores the transition to circular agriculture and bioeconomy in Australia, focusing on sustainable phosphate utilization for fertilizer production. By integrating life cycle and systems engineering approaches, the project aims to optimize resource management, reduce environmental impacts, and support sustainable development. The research aligns with Australia's national priorities, contributing to innovative strategies for environmental conservation, waste management, and sustainable agricultural practices.
-
Integrated Assessment Modelling
This innovative research project integrates Industrial Ecology methods, including Life Cycle Assessment (LCA), Material Flow Analysis (MFA), and Input-Output Analysis (IOA), with Integrated Assessment Modelling (IAM) to explore low-carbon transition pathways. Utilizing the open-source MESSAGEix framework, the project will assess climate change mitigation and circular economy impacts in energy, transport, and materials sectors. Leveraging AI, digitalization, and data science, this framework aims to guide sustainable energy transitions and circular economy strategies.
-
Material Flow Accounting and Input-output Analysis for Reducing Energy Demand
This research project aims to reduce energy demand by transforming material and product consumption patterns across the supply chain. By integrating a hybrid model combining monetary-based input-output, physical, and energy data, the project will analyze historical consumption drivers over 20 years. Utilizing digitalization, AI, and data science, the project will inform sustainable consumption and production policies, contributing to climate action and enhancing resource efficiency across Australia's economy.
-
Dynamic System Modelling and Analysis for Pursuing Sustainable Bioeconomy
This project aims to develop a cutting-edge, spatially and temporally explicit systems model for sustainable aviation fuel production in Australia using bioenergy feedstocks such as microalgae, pongamia pinnata, and sugarcane. By integrating digitalization, AI, and data science, the model will assess carbon and water footprints, human health impacts, and economic viability. The project will address uncertainties and optimize bioenergy pathways, contributing to Australia's low-carbon energy future.
-
Socio-Economic and Ethical Implications of Scaling Up Green Hydrogen Production in Australia
This research explores the socio-economic and ethical challenges of scaling up green hydrogen production in Australia, crucial for achieving net-zero emissions. By analyzing current technologies, environmental impacts, and public perceptions, the study aims to develop strategies for equitable and sustainable hydrogen adoption. It integrates quantitative and qualitative methods to assess technical viability, justice issues, and stakeholder engagement, providing insights to guide policy development and promote a socially just energy transition.
-
Integration of Multi Agent Systems (MAS) and LCA for Analysing Australian Agri-food Sector
This project aims to develop a practical and comprehensive methodology for the integration of Multi Agent Systems (MAS) and life cycle assessment (LCA). In order to identify and characterize the Australian agro-system, this project will develop a prototype computational model to simulate Australian agricultural sector. Preferably, applicant has background in computer science or applied mathematics with experience in agent-based systems as well as strong interest in computation, applied mathematics, optimization and scientific programming. Successful applicant will develop skills in modelling, analysis, data management, scenario and policy formulation and the development of sustainable solutions.
-
Pursuing Circular Agriculture and Bioeconomy for Sustainable Industrial Development
This research project aims to transform agri-food systems from linear production to a circular economy by developing a comprehensive database and applying advanced life cycle and systems-based methods. The project will assess biodiversity, land use, water, and phosphorus impacts across selected food sub-sectors. Leveraging digitalization, AI, and data analytics, it will propose circular economy models for sustainable consumption and production, ensuring resilience and environmental efficiency in Australian agriculture.
-
Modelling Urban Metabolism of Cities
This research project aims to develop a holistic multi-agent-based framework to model complex urban systems like Brisbane and assess their sustainability. Leveraging digitalization, AI, data science, and analytics, the project will create a roadmap for sustainable urban development. Through comprehensive literature review, survey development, and statistical analysis, it will provide innovative solutions for urban planners and policymakers to address resource pressure, ecosystem degradation, and sustainable city growth. Keywords: sustainable urban development, multi-agent systems, AI, digitalization, urban sustainability, data science.
-
Agent-Based Modelling of Linked Circular Economies
This project explores innovative waste reduction in urban food-energy-water (FEW) nexus by integrating circular economies through Agent-Based Modeling (ABM). By simulating stakeholder decision-making, the project analyzes resource fluxes as emergent properties, identifying synergies, feedbacks, and thresholds within the FEW nexus. Leveraging digitalization, AI, and data science, the project aims to optimize urban resource management, enhancing sustainability by reducing inefficiencies and minimizing waste across interconnected systems.
-
Stocks and Flows of Metals and Mineral Resources: Quantifying Environmental Impacts and Risks
This research project explores the metal and mineral resource needs of Japanese and Korean industries, with a focus on rare earth metals and other resources supplied by Australia's mining sector. It will develop a comprehensive database to quantify resource usage and propose circular economy models for Queensland’s mining industry, leveraging digitalization, AI, and systems thinking. The project aims to align resource extraction with ecological limits while meeting international demands sustainably.
-
Digitalisation-Enabled Circular Bioeconomy for Global Transformation
This project aims to develop a digitalisation-enabled circular bioeconomy framework, focusing on the integration of advanced digital technologies with circular bioeconomy principles. The research will explore how digital tools such as AI and blockchain can enhance the sustainability of bioeconomic practices, particularly in agricultural value chains. This project will address challenges in environmental valuation, public acceptance of innovative technologies, and governance of sustainable value chains. The outcomes will contribute to policy recommendations and innovative models for the circular bioeconomy, supporting the global sustainability and digitalisation goals.
-
Transformative Approaches to Sustainable Medicines Manufacturing Using AI-Driven Circular Bioeconomy
This research project aims to revolutionize sustainable medicine manufacturing by integrating Artificial Intelligence (AI), digitalisation, data analytics, and machine learning to pursue a net zero, circular bioeconomy. The project will develop and implement innovative AI-driven models to optimize manufacturing processes, reduce waste, and enhance resource efficiency. Digital twins and advanced data analytics will be employed to monitor and improve environmental performance in real time. By aligning with circular economy principles, the project seeks to minimize environmental impact while maintaining economic and social sustainability. The outcomes will provide a scalable framework for the pharmaceutical industry to transition towards sustainable, low-carbon manufacturing.
Supervision history
Current supervision
-
Doctor Philosophy
Enhancing Sustainable Waste Management in Agri-Food Production
Principal Advisor
Other advisors: Dr Rajendra Adhikari
-
Doctor Philosophy
Life Cycle Assessment: energy efficiency to mitigate climate change in Indonesia aquaculture industry
Principal Advisor
Other advisors: Dr Zannie Langford
Completed supervision
-
2022
Doctor Philosophy
Enhancing the sustainability of food production: A methodological framework to assess and improve the sustainability of the Australian food system
Principal Advisor
-
2020
Master Philosophy
Towards better circular economy and life cycle assessment through systems thinking and examining the interrelationships among sustainability, food systems and diet
Principal Advisor
-
2019
Doctor Philosophy
How Sustainable Is Disaster Resilience? Integrating Systems Thinking Approach towards Achieving Sustainable Post-Disaster Housing Reconstruction
Principal Advisor
-
2019
Doctor Philosophy
Strengthening Clean Energy Policy to Decarbonize Indonesia's Electricity System: A Hybrid Energy Modelling & Analysis
Principal Advisor
-
2018
Doctor Philosophy
Moving towards Sustainable Construction in Malaysia: A Holistic Model for Construction and Demolition (C&D) Waste Management
Principal Advisor
-
2017
Doctor Philosophy
Measuring the environmental efficiency of food products: New knowledge for the design of Sustainable Diets
Principal Advisor
-
2020
Doctor Philosophy
Environmental implications of meeting future demand for sugarcane-based ethanol in Brazil.
Associate Advisor
Other advisors: Professor James Watson
-
2017
Doctor Philosophy
A study of carbon dioxide emissions reduction opportunities for airlines on Australian international routes
Associate Advisor
-
2017
Doctor Philosophy
Enhancing the Understanding of Urban Systems for Sustainability Transition: A Study of Urban Environmental Management in the Natural Resource-Based Industrial City of Jinchang, China
Associate Advisor
Other advisors: Dr Thomas Sigler, Dr Bob Beeton
-
2016
Doctor Philosophy
Building a Conceptual Model to Enhance Environmental Adaptive Capacity in Small and Medium Sized Enterprises: A Case Study in Vietnam'sTextile and Garment Industry
Associate Advisor
Other advisors: Dr Bob Beeton
Media
Enquiries
Contact Dr Anthony Halog directly for media enquiries about:
- Bioeconomy
- Carbon Footprint
- Carbon Neutral
- Circular Design
- Circular Economy
- Clean Energy and Hydrogen
- Climate Change
- Decarbonization
- Energy Efficiency
- Environmental Impact
- Environmental Policy
- ESG
- Green Economy
- Green Hydrogen
- Green Manufacturing
- Green Technology
- Industrial Ecology
- Life Cycle Assessment
- Low Carbon Economy
- Net Zero Emission
- Renewable Energy
- Resource Efficiency
- Sustainability
- Sustainable Agriculture
- Sustainable and Circular Innovation
- Sustainable Development
- Sustainable Supply Chain
- Sustinable Business
- Waste Management
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