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Dr. Karl Bertling has made significant contributions to pioneering imaging and sensing via laser feedback interferometry, spanning diverse laser technologies including sensors based on visible lasers, infrared surface-emitting lasers, mid-infrared inter-band cascade lasers, and terahertz quantum cascade lasers. His current research focus includes leveraging terahertz quantum cascade laser feedback interferometry for early melanoma detection and agri-photonics, as well as near-field terahertz and mid-infrared imaging of nanomaterials and nanostructures.

Prof. Bhandari is associated with the University of Queensland since 1993. He obtained his PhD from ENSIA (France) in Food Process Engineering in 1992. Professor Bhandari is Academy Fellow of The International Academy of Food Science and Technology (IAFoST), Academy Fellow of Queensland Academy of Arts and Sciences (QAAS), Fellow of Australian Institute of Food Science and Technology (AIFST) and Honorary Fellow of Nepal Food Scientists and Technologists Association (NEFOSTA).

Prof Bhandari has a major research focus on food materials science and engineering, including microencapsulation of food ingredients, glass transition-related issues in food processing and product systems and 3D printing of food materials. Professor Bhandari’s current research area also includes relating the nanostructure of the food system to its bulk properties. Presently, he is also exploring the application of nanobubbles in food processing. His past and current researches involve dairy, meat, rice, honey, probiotics, oils, fat, etc. Professor Bhandari’s research is not commodity-focused only. His primary approach to research is applying fundamental science and engineering principles to developing a relationship between process, structure, property and performance of food materials systems. Professor Bhandari has extensively investigated various micro- and nano-encapsulation processes such as spray drying, molecular encapsulation, co-crystallisation, precipitation and gel entrapment. Prof. Bhandari has developed a patented continuous method to produce microgel particles that can be used to encapsulate various functional ingredients and pharmaceutical drugs. The process has been commercialised to encapsulate probiotics. The probiotic enriched drinks (named Perkii) are available in the Australian market (https://www.perkii.com/). Bhandari has also developed a process to encapsulate lactoferrin, which has been commercialised (https://begabio.com/product-finder/inferrintm/). Prof Bhandari has done a number of pioneering works on stickiness issues of food powders encountered during drying and handling. Recently, Professor Bhandari has developed a patented technique to produce ethylene powder, which can be used for fruit ripening and other plant physiological control. Professor Bhandari has also developed a stickiness testing device that enables the measurement of the stickiness and glass transition temperature of food material by just using texture measuring instruments.

International collaborations:

Professor Bhandari has developed strong national and international research collaborations. Professor Bhandari successfully completed a collaborative research project with Nong Lam University, in Vietnam on control of rice cracking in Mekong Delta. Professor Bhandari also completed a joint research project with the National University of Singapore on glass transition mechanisms in starch. In addition, Professor Bhandari has also been collaborating his research activities in USA, Ireland, Vietnam, India, China and France. Prof Bhandari was awarded the Australia-India Council Research grant by the Department of Foreign Affairs and Trade (Australia) to develop research collaboration with National Dairy Research Institute, Karnal, India. Professor Bhandari was also a Visiting Professor of UCSI University, Malaysia and UPM, Malaysia.

Professor Bhesh Bhandari is originally from Nepal. He has maintained strong ties to his home country throughout his career. Notably, he is an Honorary Fellow of the Nepal Food Scientists and Technologists Association (NEFOSTA) and has been actively involved in initiatives to support young scientists in Nepal. In 2019, he established the NEFOSTA Young Scientist Award to motivate researchers in the field of food science and technology within Nepal (https://nefosta.org.np/articles/2/).

Grants:

Professor Bhandari has been awarded several ARC-Discovery, ARC-Linkage over the years and ARC-Industrial Transformation Research Hub grant recently. He also won grants from Horticulture Australia, Rural Industries Research and Development Corporation, Dairy Australia, Cooperation for Agriculture and Research Development (CARD funded by AusAID) Program, National Meat Industry Training Advisory Council Limited (MINTRAC), Meat and Livestock Australia (MLA), Commercialisation Australia and UNIQUEST. He has received more than $10M grant over the years.

Awards:

2024, 2023 2022, 2021, 2020 Lead Researcher in Australia in Engineering category- Food Science and Technology discipline (listed by The Australian)

2024, 2023, 2022, 2021, 2020, 2019, 2015 Highly Cited Researcher (top 1% globally) in the field of Agricultural Science by Web of Science

2023 Lifetime Achievement Award, International Association for Engineering and Food (IAEF)

2023 Minxin Award for Outstanding Contribution in Industrial Application and International Collaboration, International Conference on Food Processing and Preservation, Luoyang, China

2022 Envoy of People’s Friendship of Wuxi, Wuxi Municipal People’s Association, China

2021 Jiangsu Province Award for International Cooperation in Food Science and Technology with Jiangnan University

2019 Distinguished Alumnus Award, Anand Agricultural University, India

2017 Outstanding Drying Research Award (Asia Pacific Drying Conference, 2017)

2015 Ho Chi Minh City Award for contributing to the promotion of friendship, collaborative relations with Nong Lam University, Vietnam

2015 Bruce Chandler Book Prize for 2015, for “Food Materials Science and Engineering”. Australian Institute of Food Science and Technology (AIFST)

2013 Vice Chancellor’s Commendation Award for internationalisation, The University of Queensland

2012 Excellence in Drying Award (AFSIA award for transfer fundamentals into practice) (International Drying Symposium 2012)

2011 Q-index Award- Top 25. The University of Queensland

2005-2010 Excellence in Research – School of Land, Crop, and Food Sciences, The University of Queensland

Academy Fellow – The International Academy of Food Science and Technology (IAFoST)

Academy Fellow- Queensland Academy of Arts and Sciences (QAAS)

Fellow – Australian Institute of Food Science and Technology (AIFST)

Honorary Fellow – Nepal Food Scientists and Technologists Association (NEFOSTA)

Publications:

Prof Bhandari has authored more than 500 papers including 9 co-edited books and 40 book chapters. His co-edited book “Food Materials Science and Engineering” was published in 2012 and another co-edited book on “Handbook of Food Powders: Processes and Properties” was published in 2013. Another co-edited book "Non-Equilibrium States and Glass Transitions in Foods: Processing Effects and Product-Specific Implications" was published in Nov 2016. The new co-edited book "Handbook of Drying of Vegetables and Vegetable Products" has been published in 2017. In 2018 "Fundamentals of 3D Food Printing and Application" was published.

His publications are cited more than 50,000 times (Google Scholar H-index 114).

Editorial responsibility:

Prof. Bhandari is an Editor-in-Chief of Future Foods and Editor of Journal of Food Engineering, reputed international journals in the food science and engineering field. Professor Bhandari has also been in the editorial board of the International Journal of Food Engineering, International Journal of Food Properties, Food Biophysics, Nature-Scientific Reports, Food Science and Human Wellness, Drying Technology and Sustainable Food Technology.

Biography:

Suresh Bhatia received a B.Tech. degree in Chemical Engineering from the Indian Institute of Technology, Kanpur, and Master’s as well as PhD degrees from the University of Pennsylvania. He worked for a few years in industry in the USA, and for two years at the University of Florida, before joining the Indian Institute of Technology, Mumbai, in 1984, and subsequently The University of Queensland in 1996. His main research interests are in adsorption and transport in nanoporous materials and in heterogeneous reaction engineering, where he has authored over two hundred and eighty scientific papers in leading international journals. He has received numerous awards for his research, including the Shanti Swarup Bhatnagar Prize for Engineering Sciences from the Government of India, and the ExxonMobil Award for excellence from the Institution of Chemical EngineersHe has held an Australian Professorial Fellowship from the Australian Research Council, and is a Fellow of two major academies – the Australian Academy of Technological Sciences and Engineering, and the Indian Academy of Sciences. He served as the Regional Editor of the international journal Molecular Simulation between 2009 and 2015. He has held visiting positions at leading universities, and between 2007 and 2009 he was the Head of the Division of Chemical Engineering at UQ.

Research:

Bhatia’s main research interests are in the modelling and simulation of adsorption and transport in nanoporous materials, and in heterogeneous reaction engineering, in which he pursues both applied and fundamental research on a variety of topics. One of the current subjects is the development of models for the reaction kinetics and transport processes in the green electrocatalytic reduction of carbon dioxide, as part of the research activities of the Australian Research Council Centre of Excellence. This is a novel route to reducing carbon dioxide emissions by converting it to useful chemicals and fuels, that is rapidly gaining increasing interest. In this technique, a porous electrode of complex structure is coated with nanoparticles of an electrocatalyst, on the surface of which carbon dioxide is reduced. Carbon dioxide (either pure gas or as part of flue gas) is fed into the electrolyser and must diffuse through the electrode’s structure to react with hydrogen ions in a liquid-phase electrolyte at the surface of the electrocatalyst. An added complexity is the intrusion of the electrolyte into the electrode, leading to its flooding and to a reduction in gas-phase transport rates. Bhatia’s research aims to gain an understanding of the complex interplay between gas-phase and electrolyte transport, and interfacial reaction kinetics, combining nanoscale models of transport and electrocatalytic kinetics with macroscopic electrode level models, and develop a comprehensive approach useful for process design and scale-up.

A second stream of activity relates to the modelling of mixed matrix membranes, particularly for carbon dioxide separation from flue gas and other industrial gas streams. These are a new class of membranes comprising a nanoporous adsorbent filler such as a zeolite or metal-organic/zeolitic imidazole framework material dispersed in a polymer matrix. Such composite membranes combine the high flux capabilities of the adsorbent with the selective properties of the polymer to overcome the established Robeson upper bound for polymers. Bhatia has developed novel effective medium theory-based models for transport in finite-sized composites, which overcome limitations of existing theories that are applicable only to large systems and therefore overlook particle and system size effects. At a more molecular level, Bhatia is investigating the nanoscale interfacial structure of the polymer in the vicinity of the solid, and its influence on the interfacial transport resistance using molecular dynamics simulation methods. When the polymer-filler interaction is strong, there is local densification of the polymer, which hinders gas transport, and when this interaction is weak interfacial nano-voids are formed which reduces selectivity. Both of these distinct effects deteriorate membrane performance, and a current focus of our research is the functionalisation of the polymer to improve polymer-filler compatibility and reduce interfacial defects. The synthesis of nanoscale and macroscopic approaches holds promise for the development of a virtual tool for the De Novo design of mixed matrix membrane specific to a given separation application; and is a key goal of this research.

Another thrust of his research relates to the transport of fluids in nanopores and nanoporous materials, where he is developing practical models of transport in nanoporous materials in conjunction with simulation and experiment. Among the achievements is a new theory of transport in nanoscale pores, which leads to an exact new result at low densities superseding the century-old Knudsen model. A current focus of the research is the interfacial resistance to transport in nanpororous materials, using molecular dynamics simulations and theoretical techniques. His results have shown that interfacial resistance dominates at nanoscales and can be very significant even at microscales. The results will have importance for a range of nanotechnologies involving the infiltration of fluids in nanoporous materials, including catalysis, gas storage, adsorption, and membrane-based separations, as well as nanofluidics.

In another stream of activity, he has developed atomistic models of disordered carbons using hybrid reverse Monte Carlo simulation methods, in conjunction with neutron scattering experiments. These atomistic models have been used to investigate the adsorption and transport of adsorbed fluids in the carbon nanostructure for a variety of applications. Among the carbons examined are carbide-derived carbon-based adsorbents for carbon dioxide capture from moist flue gases and CH4/CO2 separations. The co-adsorption of water has been shown by him to have a critical influence on both equilibrium and transport properties in these applications, and strategies for mitigating this influence are being investigated by means of simulation.

An area of recent activity is the study of carbon supercapacitors, where he is developing advanced simulation-based models for the equilibrium and flow of ions in porous carbon electrodes. These models will enable the optimisation of carbon structure for maximising capacitance and enhancing charging/discharging rates.

Teaching and Learning:

Bhatia has teaching interests in chemical reaction engineering, and applied mathematics, both at the undergraduate and postgraduate levels.

Projects:

1. Simulation of the kinetics of electrocatalytic reduction of carbon dioxide. The electrocatalytic transformation of carbon dioxide to useful chemicals and fuels is a subject of much current interest to the goal of a net zero carbon economy. This project aims to develop a model of the kinetics of the electrocatalytic reaction and use it to optimise the structure and loading of the electrocatalyst layer on the surface of the electrode. A combination of Quantum calculations and kinetic Monte Carlo simulations will be performed to determine the reaction kinetics for the carbon dioxide reduction to specific products such as ethylene and urea. Machine learning will be used to correlate intrinsic reaction kinetics with ionic concentrations in the electrolyte. Subsequently, reaction-diffusion modelling in the electrolyte will be performed to determine the optimal properties of the catalyst layer for maximising production rates. Validation of the models will be conducted using experimental data from other groups in the ARC Centre of Excellence for Green Carbon Dioxide Transformation.
2. Multiphase transport in packings of nanospheres. Numerous materials comprise packings of nano-sized particles. Examples are catalytically active layers of metals deposited on surfaces, layers of carbon nanoparticles in electrodes, and extrudates of catalyst and adsorbent particles comprised of aggregated nanoparticles. Current models of transport through such materials often simplify the structure by appealing to an idealised cylindrical pore model, which is often inaccurate and requires the use of empirical fitting parameters. In addition, such models frequently overlook fluid-solid interactions that become important at nanoscales. This project will investigate simultaneous gas and liquid electrolyte transport in packings of nanospheres, while considering fluid-solid interaction and phase equilibrium between gas and liquid, using molecular dynamics simulations, to determine multiphase transport properties as a function of interaction parameters, packing structure, packing density and particle size, and the results corelated using machine learning models. The models developed will be useful in the design of catalyst and adsorbent particles, and of electrodes in electrochemical processes.
3. Modelling transport in diffusion electrodes. Numerous electrochemical systems, such as fuel cells and electrocatalytic reactors use electrodes of complex structure, comprising a fibrous gas diffusion layer, a conductive carbon particle layer and a catalytic layer. The electrode separates gas and liquid electrolyte, both of which infiltrate the electrode from opposite sides. A reliable model of the electrode behaviour is essential for process design. This project will model the interplay between gas and electrolyte transport and their phase equilibrium in the electrode, as well as the reaction-diffusion process in the catalytic layer facilitated by the charge transport in the electrode. Joule heating of the electrode will also be considered. The particular process targeted is the electrocatalytic conversion of carbon dioxide. The outcome will be a comprehensive model of reaction and transport in the electrode that can be used in process design and scale-up of the electrochemical cell for electrocatalytic carbon dioxide reduction.
4. Synthesis and modelling of mixed matrix membranes. Mixed matrix membranes comprising a zeolite, metal-organic framework material, or other suitable adsorbent dispersed within a polymer matrix are attracting considerable attention because they combine the good mechanical properties of the polymer matrix with separation properties of the adsorbent. Here, we will perform molecular dynamics simulations of the separation of CO2 from flue gas using mixed matrix membranes and investigate their transport properties in this application. Suitable functionalisation of the polymer will be performed in silico to alleviate interfacial defects. Machine learning will be used to correlate transport properties with fundamental molecular level polymer and filler properties. Mathematical models of permeation through the membrane will be developed and validated against experimental data.
5. Dynamics of mixture adsorption in nanoporous materials. This project focuses on understanding the diffusion of gases in nanoporous materials, which is challenging both from a fundamental and applications viewpoint. Existing models frequently overlook fluid-solid interactions and require fitting parameters. In this connection, we have already performed molecular dynamics studies with single component systems and developed a novel new theory of diffusion and transport of adsorbates in nanoporous materials. The new studies now proposed focus on gas mixtures, and the theory developed will be extended to multicomponent systems in conjunction with molecular dynamics simulation. A system of particular interest is the separation of carbon dioxide from flue gas using nanomaterials and membranes.

Dr. Konstanty Bialkowski’s research interests lie in the area of communication systems, passive radar and signal processing, and specifically in the areas of wireless communication, and the use of multiple antennas or sensors for communication, radar and imaging systems. In these fields, a software-defined-radio (SDR) is an extremely useful tool, allowing practical experimentation in specific areas like high reliability or high data rate communications, radio-frequency identification, wireless sensing and biological applications.

Some key contributions have been in the development of architectures to collect information from various sensors including RF, vibration and acoustic signals; as well as sensor algorithms for passive radar, where using multiple receivers is capable of resolving target location in 3D space, rather than just the range and Doppler; and showing that SDRs can be used to develop low cost biomedical imaging devices.

Dr Steffen Bollmann joined UQ’s School of Electrical Imaging and Computer Science in 2020 where he leads the Computational Imaging Group. The Group is developing computational methods to extract clinical and biological insights from magnetic resonance imaging (MRI) data. The aim is to make cutting-edge algorithms and tools available to a wide range of clinicians and researchers. This will enable better images, faster reconstruction times and the efficient extraction of clinical information to ensure a better understanding of a range of diseases. Dr Bollmann was appointed Artificial Intelligence (AI) lead for imaging at UQ’s Queensland Digital Health Centre (QDHeC) in 2023.

His research expertise is in quantitative susceptibility mapping, image segmentation and software applications to help researchers and clinicians access data and algorithms.

Dr Bollmann completed his PhD on multimodal imaging at the University Children’s Hospital and Swiss Federal Institute of Technology (ETH) Zurich, Switzerland.

In 2014 he joined the Centre for Advanced Imaging at UQ as a National Imaging Facility Fellow, where he pioneered the application of deep learning methods for quantitative imaging techniques, in particular Quantitative Susceptibility Mapping.

In 2019 he joined the Siemens Healthineers collaborations team at the MGH Martinos Center in Boston on a one-year industry exchange where he worked on the translation of fast imaging techniques into clinical applications.

Liam is an Associate Professor in Telehealth and Director of Telehealth Technology for the University of Queensland’s Centre for Online Health.

Liam has a PhD in Medicine. His research is centred on pragmatic trials of telehealth services. Liam has a special interest in the use of telehealth for Indigenous health and rural health care delivery. He is involved in telehealth service development, delivery and evaluation across a broad range of telehealth services. Liam uses implementation research principles to understand why telehealth services work well in some scenarios and not others. He evaluates the effectiveness of telehealth from multi-disciplinary perspectives including clinical effectiveness, patient perspectives, economic aspects, organisational aspects, and socio-cultural, ethical and legal aspects.

Liam also has an active research agenda in health informatics, in particular, in imaging informatics. Liam’s work focusses on skin imaging for melanoma detection. Liam chairs dermatology working group for the DICOM standards development organisation as well as the technology standards working group for the International Skin Imaging Collaboration: Melanoma Project. This project is an academia and industry partnership designed to facilitate the application of digital skin imaging to help reduce melanoma mortality. Liam is technology lead for the Australian Centre of Excellence in Melanoma Imaging and Diagnosis. Liam has previously been a member of the Standards Australia IT-014 Health Informatics technical committees for telehealth and messaging and communication.

Liam is Vice-President of the Australian Telehealth Society and an executive member of the International Teledermatology Society.

Liam has 25 years industry experience as a health informatician. His immediate past role was the Manager of Medical Imaging Informatics at the Royal Brisbane and Women’s Hospital. Previously, Liam had over a decade’s clinical experience as a diagnostic radiographer.

Before joining the University of Queensland, Dave P. Callaghan held positions within industry including Parsons Brinckerhoff and Lawson and Treloar and research sector including Nederlands Instituut voor Ecologie and the University of Queensland. He is an observer of the Queensland Water Panel and active in the newly created Australian Hydraulic Modelling Association. He is the author of a book section and more than 50 other technical documents with applied and research applications. He is a consultant to private and government organisations. He has worked recently with private and government organisations to improve understanding of extreme coastal weather responses. He is recognised for leading edge research in coastal engineering including statistics of extremes, beach erosion from extreme events, physical and biological interactions of salt marshes and coral reefs, lagoon dynamics and wave propagation.

Biography:

Ian Cameron is a professor at the School of Chemical Engineering, an inaugural Senior Fellow of the Australian Learning and Teaching Council and ALTC Discipline Scholar in Engineering & ICT. He is also a director and principal consultant at Daesim Technologies, Brisbane. He is a Fellow of the Australian Academy of Technological Sciences and Engineering (ATSE).

He completed Chemical Engineering degrees at the University of NSW, and a masters degree at the University of Washington. He worked for 10 years for the CSR Group in diverse industry sectors such as sugar, building materials and industrial chemicals, having roles in process and control system design, plant commissioning, production management and environmental protection.

He obtained his PhD and DIC from Imperial College London in the area of Process Systems Engineering (PSE), and then worked full-time for 3 years as a United Nations (UNIDO) process engineering consultant in Argentina and a further 6 years in Turkey on a part-time basis. He has spent the last 25 years in research, consulting, teaching and learning innovation at The University of Queensland, having received numerous awards including the J.A. Brodie Medal of the Institution of Engineers Australia, the Australian Award for University Teaching in Physical Sciences 2003 and the Prime Minister’s Award for University Teacher of the Year. He was part of the team from UQ Chemical Engineering that won a national AAUT institutional award in 2005 for educational enhancement via project centred curriculum and course innovation.

He has held visiting appointments at Imperial College London, University College London, the Technical University of Denmark, the Hungarian Academy of Sciences and the University of Edinburgh.

Research:

Ian’s research interests are in Process Systems Engineering, granulation, risk management, intelligent systems and engineering education. He has published over 220 international journal and conference papers in these and related areas.

His current work focuses on innovative methodologies to detect and analyse failures in process systems, including human factors. He also applies systems thinking to innovative design and design tools for higher education curricula in engineering. He has created numerous 4D virtual systems in conjunction with industry that are now deployed and used globally.

He is the co-author of 4 books, including a process systems modelling book used in over 35 countries, as well as a widely used book giving a comprehensive treatment of industrial process risk management based on almost 30 years of research and consultancy work.

Teaching and Learning:

Since arriving at UQ, Ian has been deeply involved in course and curriculum design innovation, having established, and taught, numerous project based courses around process systems engineering. He consults widely to the national and international engineering sector on curriculum design issues. He has recently been involved in educational aspects of Skolkovo Tech, a joint venture between MIT and the Russian government.

Projects:

1. Blended hazard identification methodologies for advanced process diagnosis
2. Resilience engineering: theory and practice
3. Improved decision making via 4D+ virtual learning systems
4. Innovative curricula design tools for higher education

Wenran Cao is a postdoctoral research fellow at the Centre for Water in the Minerals Industry (CWiMI) in the Sustainable Minerals Institute. With a track record of successfully delivering short- and long-term research/industry projects, he has developed expertise in conducting field investigation, in-situ measurements, and soil/water sampling, as well as collecting, analysing, and interpreting experimental data to produce insightful reports. He also specialises in developing theoretical and numerical models of physical and geochemical coupling to tackle water-related challenges, as well as conceptualising and implementing groundwater monitoring systems with remote access.

Shakes an imaging expert that leads a strong deep learning, artificial intelligence (AI) focused research team interested in medical image analysis and signal/image processing applied to many areas of science and medicine. He received his Ph.D in Theoretical Physics from Monash University, Melbourne and has been involved in applying machine learning in medical imaging for over a decade.

Shakes’ past work has involved developing shape model-based algorithms for knee, hip and shoulder joint segmentation that is being developed and deployed as a product on the Siemens syngo.via platform. More recent work involves deep learning based algorithms for semantic segmentation and manifold learning of imaging data. Broadly, he is interested in understanding and developing the mathematical basis of imaging, image analysis algorithms and physical systems. He has developed algorithms that utilise exotic mathematical structures such as fractals, turbulence, group theoretic concepts and number theory in the image processing approaches that he has developed.

He is currently a Senior Lecturer and leads a team of 20+ researchers working image analysis and AI research across healthcare and medicine. He currently teaches the computer science courses Theory of Computation and Pattern Recognition and Analysis.

Hubert Chanson is Professor of Civil Engineering at the University of Queensland, where he has been since 1990, having previously enjoyed an industrial career for six years. His main field of expertise is environmental fluid mechanics and hydraulic engineering, both in terms of theoretical fundamentals, physical and numerical modelling. He leads a group of 5-10 researchers, largely targeting flows around hydraulic structures, two-phase (gas-liquid and solid-liquid) free-surface flows, turbulence in steady and unsteady open channel flows, using computation, lab-scale experiments, field work and analysis. He has published over 1,250 peer reviewed publications including two dozen of books. He serves on the editorial boards of International Journal of Multiphase Flow, Flow Measurement and Instrumentation, and Environmental Fluid Mechanics, the latter of which he is currently a senior Editor. He chaired the Organisation of the 34th IAHR World Congress in June 2011 and of the 22nd Australasian Fluid Mechanics Conference in December 2020, both held in Brisbane, Australia.

Dr Archie Chapman is an Associate Professor in Computer Science in the School of IT and Electrical Engineering.

Archie develops and applies principled artificial intelligence, game theory, optimisation and machine learning methods to solve large-scale and dynamic allocation, scheduling and queuing problems. His recent research has focused on applications of these techniques to problems in future power systems, such as integrating large amounts of renewable power generation and using batteries and flexible loads to provide power network and system services, while making best use of legacy network and generation infrastructure.

Prior to joining UQ, Archie was Research Fellow in Smart Grids at the University of Sydney (2011-2019), and a postdoc fellow at the University of Southampton (2009-2010), where he completed his PhD.

Learning a foreign language is hard. Studying overseas in a foreign language is even harder!

Universities in Australia have up to 40% international students, that's 400,000+ students and makes up a significant portion of the Australian economy. These students face immense struggles adapting to Australian culture, language and education style. Without help, these students get lost in the complexities of higher-education and cannot successfully graduate.

Shaun's work involves developing innovative solutions with partner universities across the greater Asian regions though contextualised development programs, workshops that highlight modern teaching, and assisting students in acclimatising to their study-life in Australia. Shaun works heavily with China, India, Sri Lanka, Taiwan, Malaysia, and Singapore.

Jeff Chen is a pyrometallurgist with strong expertise in high-temperature phase equilibria and gas/solid reaction kinetics. He has over 15 years of research experience in extractive metallurgy, focusing on metals such as Cu, Pb, Ni, PGM, and Fe, through ongoing research collaborations with major mining and metal producers worldwide. Jeff has successfully secured over 10 million dollars in research funds from the Australian government and industry, primarily through funding schemes like ARC linkage and Trailblazer. His contributions to the field include the publication of over 60 papers in leading journals and major conferences in metallurgy, and he was awarded the Best Paper Award from TMS in 2021.

In addition, Jeff is a recognised expert in various quantitative microanalysis techniques, including electron microprobe (WDS) and laser ablation ICP-MS. His specialization lies in the application of quantitative microanalysis in the field of extractive metallurgy. He played a pioneering role in implementing LA-ICP-MS for trace element analysis in metallurgical materials and has consistently contributed to the development of new standard reference materials for sulfides and alloys. From 2018 to 2021, he served as the state representative for the Australian Capital Territory (ACT) in the Australian Microbeam Analysis Society.

Furthermore, Jeff has been actively involved in university teaching, covering subjects such as chemical thermodynamics, pyrometallurgy, and metal production and recycling

Professor Chen graduated with a Bachelor of Science in Chemical Engineering from the Massachusetts Institute of Technology and a Ph.D. in chemical engineering from the University of Minnesota. She has over twenty five years research experience in the areas of membrane separation, gas separation, biocatalytic systems, nanomaterials, and water treatment. She was professor of chemical engineering at the University of New South Wales from 2008 - 2018, the Director of the UNESCO Centre for Membrane Science and Technology from 2006 - 2014 and head of school of chemical engineering fron 2014 - 2018. She is currently on the editorial board for the Journal of Membrane Science and was formerly on the editorial board for Desalination Journal.

She currently holds ARC Discovery grants ("Putting MOFs to Work on Interfaces") and has recently held funding from diverse sources such as CO2CRC, Coal Innovation NSW, ARC Linkage program, and CRC-P (Printed Energy).

Prof. Dr Zhigang Chen is currently an Honorary Professor in the School of Mechanical & Mining Engineering, the University of Queensland, and a founding director for the ARC Research Hub in Zero-emission Power Generation for Carbon Neutrality (ZeroPC), ARC Future Fellow, Academic Reseach Lead, and a Capacity Building Professor of Energy Materials at the School of Chemistry and Physics, Queensland University of Technology (QUT). Dr Chen received his PhD from the Institute of Metal Research, Chinese Academy of Sciences in 2008 under the supervision of Professor Hui-Ming Cheng, and Professor Gaoqing (Max) Lu. His research focuses on thermoelectrics for power generation and cooling; next-generation optoelectronic devices and functional System; topological insulators for next-generation chips; and high-speed sensors. In total, Dr Chen received ~A$40,000,000 in research grants to support the research, including one prestigious UQ postdoctoral fellowship (2009), ARC APD Fellowship (2009), five ARC Discovery Grants (four as lead CI, one as ARC APD fellowship, and one as ARC Future Fellowship), two ARC Research hub, four ARC Linkage Grant (one as lead CI), four ARC LIEF Grant, >10 Industry Investments (eight as sole CI), two Queensland Smart Futures Funds (sole CI), and >10 University Grants. Currently, Dr Chen is leading one ARC Research Hub, two ARC discovery projects, one sub project at ARC Research Hub, one ARC Linkage project, and four industry investments. Dr Chen is one Clarivate Highly Cited Researcher (Top 0.1% researcher in the world). He has authored over 330 high-impact journal publications including 1 Nature Energy, 1 Nature Nanotechnology; 3 Nature Communications; 1 Chemical Reviews; 2 Progress in Materials Science; 4 Energy & Environmental Science; 1 Joule; 11 Advanced Materials; and 4 Journal of the American Chemical Society. These publications have attracted >35000 times (Scopus, www.scopus.com/authid/detail.uri?authorId=57188708630) and an H index of 70. His google scholar citation is >25,000 with an H index of 100 (https://scholar.google.com.au/citations?user=vkRX_vgAAAAJ&hl=en). Particularly, in the last three years, Dr Chen has published more than 40 articles per year and attracted over 5,000 citations per year. Dr Chen has delivered over 50 plenary/keynote/invited talks in the international/national conferences. Dr Chen has authored four commercialized patents, which have been attracted industry investments.