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Brian C. Lovell, born in Brisbane, Australia in 1960, received his BE in Electrical Engineering (Honours I) in 1982, BSc in Computer Science in 1983, and PhD in Signal Processing in 1991, all from the University of Queensland (UQ). Currently, he is the Project Leader of the Advanced Surveillance Group at UQ. Professor Lovell served as the President of the International Association of Pattern Recognition from 2008 to 2010, is a Senior Member of the IEEE, a Fellow of the IEAust, Fellow of the Asia-Pacific AI Association, and has been a voting member for Australia on the Governing Board of the International Association for Pattern Recognition since 1998.

He is an Honorary Professor at IIT Guwahati, India; an Associate Editor of the Pattern Recognition Journal; an Associate Editor-in-Chief of the Machine Learning Research Journal; a member of the IAPR TC4 on Biometrics; and a member of the Awards Committee and Education Committee of the IEEE Biometrics Council.

In addition, Professor Lovell has chaired and co-chaired numerous international conferences in the field of pattern recognition, including ICPR2008, ACPR2011, ICIP2013, ICPR2016, and ICPR2020. His Advanced Surveillance Group has collaborated with port, rail, and airport organizations, as well as several national and international agencies, to develop technology-based solutions for operational and security concerns.

His current research projects are in the fields of:

• Artificial Intelligence
• StyleGAN
• Stable Diffusion
• Deep Learning
• Biometrics
• Robust Face Recognition using Deep Learning
• Masked Face Recognition for COVID-19 Pandemic
• Adversarial Attacks on AI Systems
• Digital Pathology
• Neurofibroma Detection and Assessment
• Object Detection with Deep Learning

I am actively recruiting PhD students in Artificial Intelligence to work with my team. If you are interested and have a strong record from a good university, with a publication in a good conference such as CVPR, ICCV, ECCV, or MICCAI please send your CV to me. Full Scholarships (Tuition and Living) can be awarded within one month for truly exceptional candidates.

Dr. Mingyuan Lu was awarded her PhD from The University of Queensland in Febuary 2014. She has previously completed a Masters of Engineering (June 2009, Materials Science and Engineering, Central South University, China), and a Bachelor of Engineering (June 2007, Materials Science and Engineering, Central south University, China).

Mingyuan has more than 10 years’ experience in research, and during this period she has gained extensive experience with material synthesis, mechanical mechanics, and material characterization including nanoindentation, nanoscratching, atomic force microscopy, electron microscopy, and focused ion beam milling (FIB); additionally,she has experience with structural and compositional analysis techniques (Raman, XRD, EDS, DTA, DSC etc.).

Mingyuan's contributions to the field of mechanical and materials engineering are listed below:

Materials mechanics

• (2015-2016) developed a new and successful FIB-machined micro-cantilever bending technique to study the fracture and interfacial properties of the protective intermetallic coatings on magnesium alloys: this technique can be applied to a wide range of materials, sub-surface structures and multilayered structures. Based on this methodology, they later developed a micro-bridge four-point bending technique. This approach can generate a “stable” interfacial delamination, and thus enables quantitative analysis of interfacial toughness.
• (2011-2014) developed an indentation-based methodology for assessing the interfacial adhesion of bilayer structures, in a joint project that was funded by WIN Semiconductor Co., Taiwan: the methodology developed has been used to test the reliability of SiN-passivated GaAs semiconductor wafer products.

Materials synthesis and processing

• (2015-current) developing a selective laser sintering process for the additive manufacturing of porous and biodegradable scaffolds, made from a biopolymer, for bone tissue engineering: this innovative process can produce scaffolds without the use of an artificial 3D model, and the scaffold has a unique interconnected pore architecture and large surface area making it suitable for bone tissue regeneration applications. The promising outcomes of the preliminary study have elicited strong support from UQ; it has received two generous internal grants (a philanthropic grant for an ECR in the field of engineering, and SEED funding) to enable further study in this field. The scaffolds will shortly be tested in a pre-clinical mouse model (funded by SEEM grant) to study biocompatibility and osteoconductivity.
• (2007-2009) developed high-performance refractory metallic materials using powder metallurgy processes: in this project, they discovered the effect of trace TiC, ZrC Carbide nanoparticles on the mechanical properties, sintering behaviour and microstructure of molybdenum alloys.

Dr. Yuanshen Lu began his current role at the University of Queensland (UQ) as a DECRA Fellow and Lecturer in September 2019. Previously, he was a Lecturer in Mechanical Engineering at Griffith University, following several years of postdoctoral research experience at UQ. He received his PhD in Mechanical Engineering in 2015.

Dr. Lu’s primary research interests lie in energy conversion and thermo-fluids within conventional and renewable energy systems, as well as hydrogen utilization. His current work focuses on heat engines (e.g., supercritical CO₂ power cycles), turbomachinery (e.g., wind turbines), and heat management in energy systems, including applications in heat exchangers, cooling towers, ground-source heat pumps, and thermal management in hydrogen-based steelmaking processes.

Dr. Lu is actively engaged with industry and has contributed to sectors such as thermal power generation, coal seam gas, HVAC, renewable energy, and steel industry. Leveraging his expertise in advanced experimentation and modeling, he is dedicated to driving innovations in energy harvesting, power consumption, and energy savings across a range of renewable applications. Dr. Lu currently serves as UQ’s Program Leader in the Australian Solar Thermal Research Institute (ASTRI) program, leading the Power Conversion team in developing supercritical CO₂ power cycles. He is also the Deputy Director of the Centre for Multiscale Energy Systems (CMES) at UQ.

A/Professor Bin Luo is currently an ARC Future Fellow and Group Leader in Australian Institute for Bioengineering and Nanotechnology (AIBN) at the University of Queensland (UQ). He received his doctoral degree in Physical Chemistry from National Center for Nanoscience and Technology (NCNST), University of Chinese Academy of Sciences (UCAS) in July 2013. In August 2014, Dr Luo joined UQ as a Postdoctoral Research Fellow in AIBN. He then secured highly competitive UQ Postdoctoral Research Fellowship (2015-2018), ARC DECRA Fellowship (2018-2021), and ARC Future Fellowship (2021-2025).

Research interests in Luo group mainly include

• Design of functional materials for next generation energy storage applications, including multivalent metal batteries, redox flow batteries and solid state batteries.
• Exploring new conceptual energy conversion or storage systems (e.g. flexible/micro-batteries, solar rechargeable battery).
• Revealing the structure-performance relationship of functional materials via in/ex situ investigations.
• Interaction of biomaterials and energy storage.

Professor Kristen Lyons is a public intellectual with over twenty years experience in research, teaching and service that delivers national and international impacts on issues that sit at the intersection of sustainability and development, as well as the future of higher education. Trained as a sociologist, Kristen is comfortable working in transdisciplinary teams to deliver socially just outcomes, including for some of the world's most vulnerable communities. Kristen works regularly in Uganda, Solomon Islands and Australia, and her work is grounded in a rights-based approach. In practice, this means centring the rights and interests of local communities, including Indigenous peoples, in her approach to research design, collaboration, and impacts and outcomes. Kristen is also a Senior Research Fellow with the Oakland Institute.

Dr Xiaodong Ma obtained his Bachelor's Degree in 2006 and a Master Degree in 2009 from Dalian University of Technology, China, then graduated with a PhD in 2012 from The University of Tokyo, Japan, supported by the Japanese Government (Monbukagakusho: MEXT) Scholarship.

Dr Ma joined The University of Queensland in 2012 right after his PhD graduation starting as a postdoctoral research fellow.

Dr Ma is now the acting group leader of the High-Temperature Processing (HTP) group and leading the HTP Program at JKMRC, SMI of UQ. He is an expert in the experimental and modelling research on thermodynamics and kinetics of high-temperature materials processing for ferrous, non-ferrous and advanced materials. He has extensive hands-on experiences in fundamental study and applied research including solar cell silicon purification, ironmaking, steel secondary refining, copper smelting, metal extraction from low-grade complexed ores, and waste treatment, etc. His research activities also extend to the development of high-strength and high-end specials steels by sophisticated control of second phase particles. Along with the research, he is also good at materials characterization by operating the analytical facilities of SEM, EPMA, TEM, XRD, ICP, etc. He is a pyrometallurgical specialist with a strong interest lying in the decarburization of ironmaking and steelmaking with hydrogen metallurgy and lower CO2 emission technologies in the metallurgical sector.

Dr Hui Ma received his B.Eng and M.Eng from Xi’an Jiaotong University (China), M.Eng (research) from Nanyang Technological University (Singapore), and PhD from the University of Adelaide (Australia). He has been working at the University of Queensland (Australia) since 2008. From 1997 to 2003, Dr Ma was an engineer in Singapore and made contribution to the design, development and deployment of the Intelligent Self-recovery and Automated Cargo Inventory Control System for Singapore Airline SuperHub 2.

Dr Ma's current research and development work is associated with Australian electricity supply industry. His research is centred on Electrical Asset Management including (1) modelling, sensing, and signal processing to improve the visibility of electricity networks and assets condition; and (2) data mining with uncertain reasoning for various applications of electricity networks with high penetration of renewables. Dr Hui Ma is an editor for IEEE Transactions on Power Delivery and a memebr of IEEE Smart Grid Steering Committee. He is also a member of CIGRE Australian Panel D1.

Dr Ma's course coordination and teaching:

ELEC2400 (Electronic Devices and Circuits)

ELEC4320 (Modern Asset Management and Condition Monitoring in Power System)

Dr Ma also coordinated and taught ELEC4400/EELC7402 (Advanced Electronic & Power Electronics Design) and ELEC7051 (Transformer Technology Design and Operation).

Cristián Maluk is a Senior Lecturer of Civil Engineering. His background is in structural fire engineering and in the broader scope of fire safety science. His research interests are in the fire performance of building construction materials and the resilience of structural systems during and after fire. Cristian has coordinated and contribute towards research studies in the fire safe design of structural concrete systems prestressed with fibre reinforced polymer tendons, heat-induced concrete spalling, performance of intumescent coatings under non-standard heating regimes, and developing novel fire testing methods.

Teaching and Learning

• Introduction to Fire Safety Engineering
• Fire Design for Implicit Safety
• Fire Dynamics Laboratory
• Structural Fire Engineering
• Introduction to Structural Design
• Engineering of Small Buildings

Awards

• Best Poster Award at the 10th International Conference on Structure in Fire (SiF), Belfast, UK, 2018.
• Recipient of the International Association of Fire Safety Science (IAFSS) Best Thesis Award “Excellence in Research” (years 2014-2016) to be presented during the 12th International Symposium on Fire Safety Science (IAFSS), Lund, Sweden, 2017.
• Finalist of the Best PhD Thesis Award from the International Institute for FRP in Construction (IIFC). Award competition took place during the Composites in Civil Engineering (CICE) conference to be held in Hong Kong, 2016.
• Recipient of the Thomas Howard Medal from the Institution of Civil Engineers (ICE).
• Price for 2016 Best Paper in the Journal of ICE Construction Materials.
• Recipient of the Philanthropic Grants for Early Career Engineering Researchers from the Faculty of Engineering, Architecture and Information Technology, The University of Queensland.
• Best Paper Award at the 2nd Postgraduate Conference on Scotland Infrastructure and Environment, Edinburgh, UK, 2014.
• Best Poster Award at the 11th International Symposium on Fire Safety Science (IAFSS), Christchurch, New Zealand, 2014.
• Recipient of the John Moyes Lessells Scholarship from The Royal Society of Edinburgh, Edinburgh, UK, 2013.
• Recipient of the Training School Travel Grant for Young Researchers on Integrated Fire Engineering and Response (COST TU0904) – Key Issues for the Future of Fire Engineering, Naples, Italy, 2013.
• Best Poster Award at the 10th International Symposium on Fire Safety Science (IAFSS), Maryland, USA, 2011.

Professor Darren Martin FTSE

A Translational Materials Scientist and Intensive Connector, Darren's work sits at the nexus of three key themes of strong fundamental materials science, safe biomaterials and nanomaterials and scalable advanced manufacturing

Darren has always had a strong passion for translation, as evidenced by the following four major research translation outputs, which share the capacity of advanced materials to enable impacts in health, sustainability, and social empowerment:

1996-2012 - Aortech Biomaterials Ltd: We developed a more biostable pacemaker lead insulation which is now implanted in over 80 million people worldwide (Abbott Medical).

2001-2020 - TenasiTech Pty Ltd: In 2020 our scratch resistant and break-proof acrylic glass technology was sold to RTP, a multinational plastics compounder who now sell into several large markets (appliances, personal care, construction, cell phone cases, automotive parts, etc).

2011-2022 - Spinifex Nanocellulose Platform Technology: In 2021, this technology was licensed to Brisbane startup Trioda Medical Pty Ltd for the development of injectable medical gels.

2015-Present - Sorghum-derived Microfibrillated Cellulose (MFC): My team have demonstrated that sorghum grasses can be pulped and refined into MFC in a far more sustainable manner than wood biomass.

International Collaborators and Industry Partners

Professor Martin’s current international collaborators include Stony Brook University (USA), DTU (Denmark) and IIT-Delhi (India). He also has several materials co-development projects and collaborations with companies such as Advanta Seeds, GSA Innovation, Opal Paper, Cardia Bioplastics, GMG, GrapheneX, Duromer, OPS, Dulux, Australian Wood Fibre and others.

Prizes, Honours and Awards

Excellence & Commercialisation

• 2020 - UTS Chancellor’s Award (awarded to the top Alumni from the whole of UTS each year)

• 2020 - UTS Alumni Award for Excellence - Faculty of Science • 2016 & 2019 - 2 UQ Partners in Research Excellence Awards (PIREAs) (Spinifex project Bulugudu partnership)

• 2015 - State finalist in the 2015 Telstra Business Awards (TenasiTech Pty Ltd)

• 2010 - UQ Faculty of Engineering, Architecture and Information Technology Commercialisation Award

• 2010 - Engineers Australia Nanoengineering Panel

• 2007 - iLab Prize at the QLD Enterprise Awards (lead to TenasiTech pre-seed investment from UniSeed)

Service & Leadership

• 2021 - ATSE Reconciliation Action Plan reference group and Industry and Innovation Forum

• 2021 - ATSE President Nominations and Interview Committee to deliberate on the current ATSE President

• 2019 - UQ Teams Leadership Award (Spinifex project Bulugudu partnership)

• 2019 - Business Higher Education Round Table Award (Community Engagement Bulugudu partnership)

• 1993 - Member of the Royal Australian Chemical Institute RACI and the RACI QLD Polymer Group

Dr Veronica is an Advance Queensland Industry Research Fellow, under the supervision of Professor Esteban Marcellin and Professor Lars Nielsen. She received her Biotechnology Engineering degree at the University of Chile in 2007 and completed her Ph.D. in Systems Biology at The University of Queensland in 2014. After completing her Ph.D. she performed 2 years of postdoctoral training at The University of Queensland, as part of a collaboration project with Universidad de Chile. Both Ph.D. studies and postdoctoral training were financially supported by the Chilean Government, under a competitive scholarship and fellowship, respectively. Later she worked as a Postdoctoral Research Fellow- Biopharmaceutical Upstream Bioprocessing at the ARC Training Centre for Biopharmaceutical Innovation (CBI), The University of Queensland.

She has some teaching experience. She had performed tutorial teaching in several courses at Universidad de Chile and the University of Queensland. In 2016 she was in charge of the Beer and Biofuels practical, part of the subject: Biomolecular Engineering (CHEE4020) of the chemical engineering department at The University of Queensland. In 2023 she gave an invited speaker lecture about cell culture optimization at the Biologics course (BIOT7018) at The University of Queensland.

Her research focuses on the improvement of biopharmaceutical production using mammalian cells. She is specifically interested in (1) the development of computational tools for metabolic systems biology, and (2) the improvement of upstream bioprocess. On the tools side, she has worked on the integration of thermodynamic principles and omics datasets into genome-scale models to estimate metabolic flux distributions; and developed a method for the estimation of dynamic metabolic fluxes. She has used these tools to describe experimental mammalian cells data and to guide the improvement of biopharmaceutical production processes. She has also been involved in the development of the latest human and CHO genome-scale models. On the process side, she worked on the improvement of a high cell density culture, using systems biology tools to develop a cell line adapted to high cell density and to develop an improved upstream bioprocess.

Her current project focuses on the development of a platform to generate good producer cell factories of difficult-to-express proteins.

Dr Mason began at The University of Queensland in late 2014 after holding academic positions at The University of Sydney and QUT. Prior to joining UQ he also worked as a catastrophe risk researcher for the industry-focused research centre, Risk Frontiers at Macquarie University. Matthew’s key areas of interest and expertise lie in the fields of:

• Wind Engineering
• Stochastic modelling of hazards, including convective storms and tropical cyclones
• Probabilistic modelling of structural and infrastructure vulnerability to wind, water and hail
• Catastrophe loss modelling for natural hazards
• Modelling and observation of the atmospheric boundary layer
• Wind tunnel testing and analysis
• Disaster insurance

Dr Mason is currently the Chair of the Standards Australia wind loading sub-committee responsible for maintenance of AS/NZS1170.2.

Dr Mostafa Kamal Masud is a CCQ Next Generation Cancer Research Fellow at the Australian Institute for Bioengineering & Nanotechnology (AIBN), the University of Queensland (UQ). In 2020, he received his PhD in Medical Biotechnology Diagnostics and Nanobiotechnology from AIBN, UQ. He received his MS and B.Sc. (Hons.) in Chemistry from Shahjalal University of Science and Technology (SUST), Sylhet-3114, Bangladesh. After completing his PhD, he was awarded a prestigious JSPS Postdoctoral Fellowship (success rate >10%) from Japan and served as a Postdoctoral Fellow at Japan's National Institute for Materials Science (NIMS).He recently been awarded a highly prestigious ARC DECRA fellowship for the period 2024-2026 and a QLD Cancer Council fellowship for the period 2024–2028. His research focuses on the development of novel nanostructures and nanodiagnostic technologies to address critical issues in medical diagnosis. As an early career researcher, he has an excellent track record with more than 60 peer-reviewed publications in prestigious and high-impact journals in the area that achieve <2800 citations with an h-index of 29 (Scholar google link: https://bit.ly/2Vtv67l). He has developed new classes of superparamagnetic nanostructures and fabricated novel biosensors for the detection of disease-specific biomolecular targets e.g., for miRNA, DNA, exosome and protein biomarker detection that have proven to be easy and effective, allowing for rapid diagnosis with minimal equipment. He made a major contribution to nanotechnology integrated-analytical and diagnostic fields by providing analytical and technological input as well as developing key collaborations with clinicians and biologists for translational research. His strategy is to create nano-architecture point-of-care diagnostic technology for early diagnosis of cancer that could hopefully lead to a healthy and happier life for humans.

I study design as a collaborative process that materialises alternative social futures. Those futures are sometimes new products, systems, services, infrastructures and technologies. But they can also be social contracts, agreements, processes, ways of working and new possibilities for our collective lives together.

I currently lead research projects in three broad domains: designing advocacy, designing the materials of participation, and augmenting skill and expertise through design.

The designing advocacy project has worked with a range of stakeholders with reduced agency such as people with mental health needs, chronic illnesses, injured workers, and other stigmatised or at-risk groups. We have developed methods for the inclusion of their perspectives in design processes, insights about their specific conditions and needs, critical analyses of how they are conceptualised from the perspectives of technologists and service providers, and design proposals for services and technologies that amplify their agency.

The designing the materials of participation project develops formats and processes for participatory design—the inclusion of stakeholders in the design of systems that will affect the organisation of their work and life. In this project we study how technologies and systems are used in microanalytic detail, analysing how tools and materials shape people's interactions. We use this understanding as a basis for the design of new methods and processes (and sometimes new matierals) for involving people in the design process, and giving them greater autonomy over the systems they will use.

The augmenting skill and expertise through design project studies specialist work practices for the purposes of developing technology support for that work. We have worked with aeromedical teams, audiologists, passport officers, emergency first responders, quick service chefs, primary school teachers, and other professional contexts of use to understand the local and particular skills that enable those workplaces to function effectively and collaboratively. We use these understandings to inform the deisgn of technologies and work practices that support, and preserve, those core professional skills.

The constants across these projects relate to the design process—the methods used to understand people, identify design opportunities, facilitate collaboration between project stakeholders, champion users' contexts and requirements, prototype early solutions, evaluate concepts in the field, and build new technologies. This results in a variety of research contributions: new design methods and perspectives that have been tailored for specific contexts of use, identification of the potentials and limitations of different approaches to design and analysis, the discovery of context-specific issues for the design of new systems, new understandings of people, their work and contexts of use, and the design and evaluation of bespoke technologies.

Professor Ross McAree is Head of the School of Mechanical and Mining Engineering at the University of Queensland. His research interests are focused on machinery dynamics and control with a current emphasis on mining equipment automation.. Professor McAree led the development and demonstration of the world’s first fully autonomous mining excavator as the outcome of a 10year collaboration with Joy Global Surface Mining (now part of Komatsu) and has collaborated with Caterpillar Inc. to develop and trial the world’s first autonomous bulldozer capable of production dozing using the ‘pivot push’ method. From 2007-2015 Professor McAree held an industry funded (P&H) Chair in Mechanical Engineering and from 2009-2015 he was Vice President for Automation and Automation Program Leader with the Cooperative Research Centre for Mining. He has attracted in excess of $12M dollars of Category 1-3 and $8.5M of Category 4 funding has contributed to the winning of two CRC bids (CRCMining and CRCMining2) for a total of $35.2M funding. He established the Mechatronic Engineering Plan at UQ in 2002. He has given leadership to his School as Chair of Research Committee (2009-2015) and Teaching and Learning Committee (2015-2017). Significant external service includes serving as Chair for the Australian Academy of Science National Committee on Mechanical Sciences (2001-2006) and as the Australian representative to the International Federation of Mechanism and Machine Theory (2001-continuing), Associate Editor for journal ‘Mechatronics’ (1999-2011) and member of Australian Standards Committees ME-27 and IT-06P. Professor McAree is a fellow of the Australian Academy of Technology and Engineering (ATSE).

Dr McDonald is a graduate of The University of Queensland (UQ) having obtained a Bachelor of Engineering (Manufacturing and Materials) in 1997 and a PhD in Materials Engineering in 2002. He is a currently a Senior Research Fellow in the Nihon Superior Centre for the Manufacture of Electronic Materials (NSCMEM).

His research is in the field of microstructure control through solidification science and in particular on understanding the effect of trace element additions on nucleation and growth phenomena. He has numerous publications and expertise in the areas of:

1. Lead-free Solder Alloys

2. Grain refinement

3. Machining and heat treatment of titanium alloys

4. Mg-based Hydrogen Storage Alloys

5. Casting and Solidification of Al-Si Alloys

6. Eutectic solidification and modification

Professor McIntyre develops and applies advanced imaging techniques to study flow environments. He conducts research within the Centre for Hypersonics where he implements a range of interferometric, spectroscopic and imaging techniques to probe the harsh environment generated in ground-based hypersonic facilities. He also has interests in the development of laser-based imaging methods in the field of Biophotonics including differential interference contrast microscopy and super-resolution coherent anti-Stokes Raman spectroscopy.

Prof David Mee's research interests are in Hypersonic and Supersonic Flow.

After completing his PhD at UQ, he spent five years as a Research Fellow in the turbomachinery research group at Oxford University in the U.K. He returned to UQ as an ARC Queen Elizabeth II Research Fellow in 1991 and joined the academic staff of the Department of Mechanical Engineering in 1993. He served as Head of the Division of Mechanical Engineering from 2007 to 2017, acting Head of the School of Engineering from January to July 2009 and Head of the School of Mechanical and Mining Engineering from July 2009 to February 2017. He retired in 2020 and is currently an Emeritus Professor in the School.

David's main areas of research are focussed in the field of hypersonics aerothermodynamics. He has undertaken much research on rapid response, stress-wave force balances, which are essential technology for categorising the performance of scramjet engines in transient facilities, such as shock tubes. He was a member of the team that conducted the first known wind-tunnel test in which a scramjet vehicle produced net thrust. He has also published on the transient processes in the latter stages of boundary layer transition in hypersonic flows.

Paul Meehan's research interests are in: Smart Machines; Railway Engineering and Technology, Analysis and Control of Nonlinear Instabilities and chaos in rolling processes, spacecraft systems and biological/human body processes, advanced manufacturing modelling and analysis.

Paul Meehan is an expert in modelling, analysis and control in non-linear mechanics applied to engineering systems. He has over 25 years experience in engineering research, development, commercialization and consulting in the areas of non-linear dynamics, vibrations, controls, rolling contact, elastoplastic and wear phenomena, with applications to manufacturing, mining, railway, spacecraft and biomedical systems. He has initiated and led many successful large collaborative R&D projects in this area.

Paul has recently led or is currently leading major projects in novel prediction and control of non-linear phenomena in railway, mining and manufacturing systems, including Decarbonisation, Bearing Degradation Phenomena, Incremental Sheet Forming, Wheel and Brake Squeal, Advanced Duty Detection and Millipede Technology. He has organised three international conferences in various areas of non-linear mechanics and has authored over 140 internationally refereed publications and three international patents in this area. He also teaches several intermediate and advanced level courses in mechanics at the University of Queensland, and consults regularly to high technology industries.