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Dr Yuan Wang's research interests are in the advanced manufacturing of metallic materials for medical and energy applications.

As an early-career researcher, he has published 35 papers attracting >3000 peer citations. All his first/co-first authored papers and corresponding authored papers were published in Top 2% journals by 2023 CiteScore. 97% of his work was published in Top 25% journals. His first authored papers have a field-weighted citation index (FWCI) of 4.14, including 1 Hot Paper (Top 0.1%) and 2 ESI Highly Cited Papers (Top 1%).

Dr Wang has a strong passion for conducting industry-outcome focussed work, particularly in exploring how cutting-edge technologies such as artificial intelligence can be applied to generate manufacturing innovations. He had also conducted extensive research in thermoelectric energy materials and devices during his PhD. His reseach has been recognised by the Advance Queensland Industry Research Fellowship (2023), UniSQ Research Excellence Award (2020), and UniSQ HDR Publication Excellence Award (2019).

Dr Wang obtained his bachelor's degree in Metallurgical Engineering from Northeastern University (China) in 2016, with his third year at UQ where he received the Dean’s Commendation for Academic Excellence Award. He completed his PhD from the University of Southern Queensland in 2020 and joined UQ afterwards first as a Postdoctoral Research Fellow, and now as an Advance Queensland Industry Research Fellow in the School of Mechanical and Mining Engineering. As the principal investigator, he has successfully secured competitive grant funding totalling >$500,000. His current project with a multinational manufacturing company represents the world’s pioneering AI-driven manufacturing innovations in the medical device industry.

Dr Wang is a lecturer of MATE7015 (Additive Manufacturing) and BIOE4305 (Biomaterials). His commitment to quality teaching is demonstrated through his SECaT score of over 4.5 out of 5.0. He is also actively engaged in a variety of supervision and service roles.

Biography:

Professor Lianzhou Wang FAA FTSE is Australian Research Council (ARC) Australian Laureate Fellow at the School of Chemical Engineering, Director of Nanomaterials Centre (Nanomac), and Senior Group Leader of Australian Institute for Bioengineering and Nanotechnology (AIBN), The University of Queensland. He received his PhD degree from Shanghai Institute of Ceramics, Chinese Academy of Sciences in 1999. Before joining UQ in 2004, he has worked at two leading national research institutions (NIMS and AIST) of Japan as a research fellow for five years. Since joining UQ, he has worked as ARC Queen Elizabeth II Fellow (2006), Senior Lecturer (2007), Associate Professor (2010), Professor (2012-now) and ARC Future Fellow (2012-16), and is now an ARC Australian Laureate Fellow at the Chemical Engineering School and AIBN.

Research:

Professor Wang's research focuses on the synthesis, characterisation and application of semiconductor nanomaterials for use in renewable energy conversion/storage systems including photocatalytsts for solar hydrogen and valuable chemical production, rechargeable batteries and low cost solar cells. In the past 20 years at UQ, as a Chief Investigator, he has attracted a large number of competitive research funds from ARC, CRC, CSIRO and industry. Prof. Wang has contributed 3 edited books, 14 edited book chapters, more than 600 journal publications (including top ranking journals such as Science, Nature Energy, Chem. Rev., Chem Soc. Rev., Nature Commmun, Angew. Chem., Adv. Mater., J. Am Chem. Soc., etc.), filed 20 patents and delivered over 130 plenary/keynote/invited presentations. His publications have received >55,000 citations with a H-index of 127 (Google Scholar). Prof. Wang is serving as Editor/Associate Editor/Editorial Board member of more than 10 international journals including Advanced Materials (Wiley Publishing group, Impact factor 32.09). He is named on the list of the Clarivate’ Highly Cited Researchers (Top 0.1% researcher in the world).

Prof. Wang has won a number of prestigious Fellowships/awards including STA Fellowship of Japan, ARC QEII Fellowship of 2006, UQ Research Excellence Award of 2008, Scopus Young Researcher Award of 2011, ARC Future Fellowship of 2012, UQ Research Supervision Award of 2018, ARC Australian Laureate Fellowship of 2019, Research Excellence Award in Chemcial Engieering of 2019, and ARC Industry Laureate Fellowship of 2024.

Prof. Wang is the elected fellow of the Australian Academy of Science (FAA), the Australian Academy of Technological Sciences & Engineering (FTSE), Academia Europaea (MAE) and Royal Society of Chemistry (FRSC). On professional services, he serves as the chair of National Committee for Materials Science and Engineering, Australian Academy of Sciences, and the President of Australian Materials Research Society.

Teaching and RHD supervision activities

• Lecturer of second year undergraduate core course CHEE2003 Fluid & Particle Mechanics and fourth year engineering course CHEE4301 Nanomaterials and Their Characterisation
• Research Supervision: 45 RHDs awarded, current supervisor/co-supervisor of ~20 PhD students & 15 Postdoctoral Fellows/Research Fellows/Senior Research Fellows.

Andrew Ward is an ARC Industry Fellow at the Australian Centre for Water and Environmental Biotechnology (ACWEB), at The University of Queensland. He holds a PhD degree from the School of Chemical Engineering (The University of Adelaide) and his thesis focused on the optimisation of halophilic anaerobic digestion of algal biomass. At ACWEB projects he has worked on include Nutrient recovery via electrodialysis and Anammox for both domestic wastewater and agricultural wastewater treatment. He previously received an Advance Queensland Industry Research Fellowship to investigate the use of algae and bacterial aggregated flocs for the remediation of wastewater. Andrew has just received and ARC Industry Fellowship to investigate the use of microalgae and its role in energy and nutrient recovery from a circular economy perspective. Andrew has significant industrial experience working with large water utilities and industry partners scaling up research to pilot and demonstration scale. Andrew is currently lead investigator and manages Urban Utilities wastewater microalgae research program.

Tony is an expert mining structural geologist who applies his skills to problems of deep earth mass mining, giant open pits, near-mine exploration, and the local and regional lithostructural controls on complex metalliferous mineral deposits. As a Senior Research Fellow in mining and engineering geology at the University of Queensland, Tony’s pioneering research focussed on the geological modelling and data inputs required for planning deep cave mining operations, an area that had received little previous consideration from geologists. He led the Geology and Mass Mining Project (GMM), which examined the geoscientific inputs required for exploring, defining, establishing, and mining block and sub-level caving operations that were being developed on giant porphyry copper-gold systems and IOCG deposits. While much research was being done in Australia to explore the deep earth environment, very little was being done to model the geology of large and deep mineralized systems, and then to use the new data and models to plan and extract any large discoveries made. Tony’s pioneering work was some of the first and most comprehensive to be done in this field.

• Fellow and chartered professional (geology) of the Australasian Institute of Mining and Metallurgy
• Fellow of the Society of Economic Geologists
• Fellow of the Geological Society
• Fellow of the Australian Institute of Geoscientists
• Member, Geological Society of Australia
• Member, Australasian Society for Historical Archaeology

Tony is presently a Principal Structural Geologist with a Brisbane-based geophysical and geological consulting group.

Prof. Wheatley is the Co-Director of the Centre for Hypersonics within the School of Mechanical and Mining Engineering. He was named Australia's Research Field Leader in Aerospace and Aviation Engineering (The Australian, Sept 28, 2018) and was a recipient of a 2017 Australian Award for University Teaching – Award for Teaching Excellence .

Prof. Wheatley's research interests are in the fields of supersonic plasma flows, hypersonics and computational fluid dynamics.

Prof. Wheatley's research in supersonic plasma flows focuses on the suppression of instabilities that are detrimental to inertial confinement fusion, a process that promises carbon free energy production. In hypersonics, he focuses on extending the capability scramjets to the point where they can power launch-vehicle stages. This technology could meet the need for safer, more economical space access, which has the potential to revolutionise the space industry. Computational fluid dynamics is his primary method of investigation in these areas.

Prof. Wheatley obtained his PhD in Aeronautics from the California Institute of Technology in 2005. He also earned an MEngSc (Mechanical) and a BE (Mechanical and Space) from the University of Queensland (UQ). After completing his PhD in the US, Dr Wheatley spent two years as post-doctoral fellow at ETH Zurich. He was then a Lecturer in Aerospace Engineering at the University of Adelaide before taking up his position at UQ in 2009.

Prof. Wheatley has expertise in the areas of:

• Simulation of hypersonic flows (DNS, LES and RANS)
• Using high fidelity numerical simulations, validated by experiments, to provide new details and understanding of scramjet flow physics
• Mixing and combustion enhancement in scramjets through fuel/flow structure interactions and novel injector design
• Analysis and simulation of plasma instabilities
• Numerical methods for magnetohydrodynamics (MHD) and multi-fluid, ion-electron plasmas
• Rarefied gas dynamics
• Bluff body wake dynamics
• Aeroacoustics, particularly passive noise control for bluff bodies

Brooke-Mai is a Lecturer in Speech Pathology and a Certified Practicing Speech Pathologist. Her research interests include the rehabilitation of motor speech disorders, brain mechanisms underpinning speech recovery, and the application of telerehabilitation to improve access to speech pathology services.

Dr. Whitmire is a group leader at the Queensland Brain Institute (QBI) and a senior lecturer in Electrical Engineering and Computer Science (EECS) at The University of Queensland (UQ). She is a leading expert in understanding how sensory information is represented along the neuraxis from the neurons in the skin that sense external stimuli to the central representation in the thalamocortical circuit. She operates at the interface of neuroscience and engineering to generate novel insights into information representation in the brain. Her laboratory uses a combination of tools to record from populations of neurons, manipulate the activity of those neurons, and model the underlying neural circuitry. Dr. Whitmire trained as a Biomedical Engineer at North Carolina State University (B. S.) and Georgia Institute of Technology/Emory Universty (Ph.D.). Following postdoctoral work at the Max Delbrück Center for Molecular Medicine, she established her own laboratory at The University of Queensland in 2023.

Professor Andrew Whittaker is Deputy Director Research, Senior Group Leader and founder member of the Australian Institute for Bioengineering and Nanotechnology (AIBN). He directs research funded through more than $61.3 million in competitive grants since 2000 and $39.7M since 2010. Professor Whittaker’s work in synthesis and characterisation of polymeric materials has underpinned major development programs in several key areas.

His work in the field of materials for photolithography has been supported by funding from leading semiconductor companies Intel, Sematech, Dow Chemical Company and DuPont. Outcomes include novel high-index resists for 193 nm immersion lithography, new concepts for design of non-chemically amplified resists for EUV lithography, novel approaches to healing roughness in IC features and block copolymer self-assembly.

In the field of biomaterials science and nanomedicine, Professor Whittaker has established a network of international scientists under the theme “Bringing Materials to Life”. He is active in developing novel imaging agents for MRI, and has introduced a new class of 19F polymeric agents. He leads research into responsive polymers for nanomedicine and for device manufacture. His work on polymeric hydrogels including transport properties is highly cited.

Finally, Professor Whittaker is an expert in the fundamentals of diffusion process in complex solids and has an international reputation in the field of NMR and MRI of polymeric systems.

International links

Professor Whittaker is a member of numerous international committees of governing bodies in polymer science and technology, and is involved in organising major international conferences. He is currently president of the Pacific Polymer Federation. He actively collaborates with scientists at the University of California Santa Barbara, USA; Institute of Nano Science and Technology, Mohali, India; Gebze Technical University, Turkey; Nagoya Institute of Technology, Japan; Jilin University, Hubei University, the National Center for Nanoscience and Technology (NCNST, CAS), SUSTech and Shanghai University, China; the University of Nottingham, UK; IMEC, DuPont Electronics and Imaging, USA. He has held visiting professor positions at NCNST, INSA Lyon and NIT, was DICE Chair at the University of Nottingham, and is currently visiting professor at Hubei University.

Dr Felix Wiesner is an Assistant Professor at the University of British Columbia and an Honorary Fellow in the School of Civil Engineering at The University of Queensland and works as part of the National Centre for Timber Durability and Design Life. He was appointed at UQ as a Lecturer in Timber Engineering in 2019 to lead research projects focused on enhancing the fire performance of timber using treatments and modification techniques. His background is in structural fire engineering and the fire safety of timber structures, specifically engineered timber structures. His field of expertise are the critical evaluation of load bearing capacity of building elements in fire and the assessment of safety implications arising from the use of engineered timber as structural members in tall buildings or structures with extraordinary architectural features.

Dr Wiesner completed his Master of Engineering in Structural and Fire Safety Engineering at The University of Edinburgh from 2010 to 2015 before he successfully completed his doctoral studies on the structural behaviour of cross-laminated timber in fire between 2015 and 2019. During his undergraduate and postgraduate work, he closely worked with Arup on multiple projects regarding the fire safety of timber buildings and the effect of localised fires in large open spaces. He actively participated in the European COST Action FP 1404 for the Fire Safe Use of Bio-Based Building Products between 2016 and 2019, representing the UK as a Management Committee member. He significantly contributed to the success of the Fires in Tall Timber Structures: Large-scale Tests in Support of Tall Timber Construction project at the BRE in the UK and also worked as a member of the global Fire Safe Use of Wood research collaboration.

Chamith completed his PhD in Electrical and Computer Engineering at the University of Akron, Ohio, USA in 2014 and BSc (Hons) degree in Electronic and Telecommunications Engineering with first class honours at the University of Moratuwa, Sri Lanka in 2007. His research interests and expertise include multidimensional signal processing, digital hardware architectures for signal processing, FPGA based system design, hardware accelerators for machine learning, and engineering education. Chamith has received a number of awards including the Outstanding Student Research Award at the University of Akron, Ohio, USA, in 2011 and he is one of the two recipients of the IEEE Circuits and Systems Pre-Doctoral Award in 2014. From 2015-2019 he was a lecturer at the School of Electrical Engineering and Telecommunications, University of New South Wales, Sydney, Australia.

Research into advanced computer architectures

John Williams, born in 1973, was awarded his Ph.D from the Queensland University of Technology (QUT), Australia, in 2001. He was previously awarded undergraduate degrees in Electronic Engineering, and

Information Technology, also from QUT, in 1995. He is currently employed in the School of ITEE at The University of Queensland, Brisbane, Australia, where he holds the position of Research Fellow.

His research interests include reconfigurable computing and real-time embedded Systems, as well as 3D computer vision and imaging. He has authored 5 refereed journal publications, and more than 20 refereed conference publications, and recently edited the Proceedings of the 2004 IEEE International Conference on Field Programmable Technology. He has been a member of the IEEE for 8 years.

Professor David John Williams is the Director of the Geotechnical Engineering Centre within the School of Civil Engineering at The University of Queensland, an industry-funded centre that has attracted AUD10 million in funding over the last 15 years. He also manages the industry-sponsored Large Open Pit Project, involving 10 global mining company sponsors, with current funding of USD1 million per year. He has over 40 years of teaching, research and consulting experience, and is internationally recognised for his expertise and experience in mine waste management and mine closure, pertaining to tailings dams in particular. He was a member of Expert Panel investigating technical causes of Brumadinho tailings dam failure and is on a number of Tailings Independent Technical Review Boards, including for Escondida. He authored in 2009 and 2016 Tailings Management Handbook, as part of the Commonwealth Leading Practice Sustainable Development Program for the Mining Industry. He is on Working Party for the Australian National Committee for Large Dams Guidelines on Tailings Dams – Planning, Design, Construction, Operation and Closure, published in 2012, with an Addendum in 2019.

David received his BE (Hons I) in Civil Engineering from Monash University in 1975 and his PhD in Soil Mechanics from the University of Cambridge in 1979. His research interests include:

• Physical characterisation of mine tailings deposition, including beaching, hydraulic sorting, sedimentation, consolidation, desiccation and loading
• Store and release cover systems for potentially acid forming mine wastes
• Co-disposal of mine tailings and coarse-grained mine wastes
• Dewatering and densification of mine tailings
• Dewatering of mineral products
• Moisture movement within mine wastes
• Settlement of coarse-grained mine wastes
• Strength of coarse-grained mine wastes
• Engineered rehabilitation of mine sites
• Risk assessment and cost-effectiveness analysis of mine site rehabilitation and closure
• Long-term seepage and runoff from mine tailings storages
• Characterisation of potentially acid forming waste rock dumps
• Application of high-resolution digital stereo-photography to monitoring erosion from mine waste slopes
• Mined landform evolution and design

Professor Wolvetang is an international leader in the area of pluripotent stem cell biology and human functional genomics. he initiated and leads Cell Reprogramming Australia, a collaborative framework that facilitates induced pluripotent stem cell research in Australa and is co-director of the UQ Centre in Stem Cell Ageing and Regenerative Engineering (StemCARE). He has extensive expertise in reprogramming somatic cells, differentiation and tissue engineering with adult, embryonic and induced pluripotent stem cells, genome manipulation with CRISPR, molecular biology, transcriptome analysis, high content image analysis, development and use of microfluidic devices for cell analysis, nanoparticle and scaffold design and delivery, and stem cell and cell-free regenerative medicine approaches.Professor Wolvetang has been instrumental in establishing and enabling the technology for derivation of induced pluripotent stem cells across Australia. Professor Wolvetang made the strategic decision to focus on the generation of induced pluripotent stem from patients with neurological and cardiac disorders because live human cells from such patients can usually not be obtained whereas induced pluripotent stem cells have the ability to generate every cell type of the human brain in unlimited amounts and can recapitulate the disease in the dish. Induced pluripotent stem cells combined with emerging technologies such as CRISPR-based genome editing offers a unique opportunity to study the role of individual genes and combinatorial gene regulatory pathways in the eatiology of monogenic and complex brain disorders. Indeed, combined with RNA-seq and organoid generation we are now for the first time able to gain insight into gene regulatory pathways operational in individual brain cell types of healthy and diseased individuals, investigate the connectivity and function of cells, as well as pinpoint where and when during early development such deregulated pathways lead to pathological changes. Induced pluripotent stem cells further not only provide insight into the underlying pathogenesis of neurological disorders but also constitute a valuable drugscreening platform and, following CRISPR-based gene correction, can form the basis of patient specific cellular therapies for currently incurable diseases.

Professor Wolvetang received his PhD in 1992 from the Department of Biochemistry, University of Amsterdam for his original work on peroxisomal disease (6 papers). He undertook postdoctoral studies at the Department of Biochemistry and the Institute for Reproduction and Development of Monash University, investigating apoptosis, Down syndrome and Ets transcription factors, respectively, obtaining the first evidence for an intra-chromosomal regulatory loop on chromosome 21 involving Ets2 (3 papers), and revealing the role of p53 in immune-suppression in Down syndrome (Hum Mol. Genetics). He then joined Prof Martin Pera in the Australian Stem Cell Centre in 2003 to pioneer human embryonic stem cell research in Australia, resulting in a first author Nature Biotechnology paper in 2006 identifying CD30 as a marker for genetically abnormal hESC (72 cites). He was appointed group leader of the Basic human stem cell biology laboratory in the ASCC research laboratory and senior lecturer in the Department of Anatomy and Cell biology until he accepted his current position as an independent group leader at the AIBN and Professor in stem cell biology at the University of Queensland in 2008. There he started to generate integration-free induced pluripotent stem cells from human neurological diseases such as ataxia-telangiectasia (Stem cells translational medicine). In recognition of his leadership role in this area of research he was appointed leader of the “Reprogramming and Induction of pluripotency” Collaborative Stream of the Australian Stem Cell Centre until the end of that initiative in 2011, coordinating collaborative research between eight stem cell laboratories across Australia. He subsequently initiated and is now the president of Cell Reprogramming Australia, a collaborative framework aiming to facilitate and accelerate iPS cell research in Australia and the Asia pacific region and inform the general public about reprogramming technology. His research continues to combine cell reprogramming technology, genome editing/analysis tools and microfluidic/nanoparticle based detection/ delivery technologies with the aim of creating human in vitro models of disease, unravel the underlying gene regulatory networks and enable novel cell- and delivery-based therapeutics, respectively. He further co-direct the UQ-Centre for stem cell ageing and regenerative engineering (UQ-StemCARE).

Olivia is a Senior Lecturer in Nutrition and Dietetics at the School of Human Movement and Nutrition Sciences, The University of Queensland and a Senior Research Fellow with the Centre for Nutrition and Food Sciences (CNAFS), The Queensland Alliance for Agriculture and Food Innovation (QAAFI). Olivia has a strong track record in leading multidisciplinary research. Her main research streams include clinical trials examining the bioavailability of nutrients and the impact on clinical outcomes and/or gene expression; the uptake and maintenance of healthy and sustainable dietary patterns; innovative models of service delivery to prevent nutritional decline and improve quality of life for older people; service co-design, delivery, and evaluation across various areas of dietetics practice. Olivia also collaborates with industry partners to trial novel foods and ingredients.

Olivia is a highly supportive postgraduate advisor, mentoring 13 PhD students (5 to completion, 3 as primary; 8 continuing). She regularly supervises Master of Dietetics Studies coursework research students (around 22 projects 2009-2022) and supervised 2 honours students (2011).

Olivia is an Associate Editor for the international journal, Nutrition Journal, (BMC, Springer Nature). In 2010, she received Advanced Accredited Practising Dietitian status, as recognition of her professional leadership and expertise and in 2011 won the Women in Technology "Rising Star" Award. She has received significant research funding, including support from the Australian Research Council, the National Health and Medical Research Council, Queensland Health and Horticulture Innovation Australia.

Yuan Xu completed a Bachelor of Engineering degree (Chemical and Material) from the University of Queensland in 2015. After that, he started his PhD in the research field of colloidal science, rheology and chemical engineering, supervised by Professor Jason Stokes. He has continued in UQ as postdoctoral research fellow since 2019, at which, he has contributed to multidisciplinary projects including viscoelastic lubrication of soft matter systems, and programming structural anisotropy in nanocellulose hydrogels. His research capability focuses on the area of rheology, colloidal science/ physical chemistry, material/physical science, soft matters/complex fluids, and tribology/lubrication.

Mohsen Yahyaei is an expert in modelling, optimising, and controlling mineral processing circuits using novel approaches and tools. He is currently the Director of the Julius Kruttschnitt Mineral Research Centre (JKMRC) and Program Leader for Future Autonomous Systems and Technologies (FAST) at the University of Queensland’s Sustainable Minerals Institute.

Mohsen completed his undergraduate studies in Mine Exploration and earned a Master’s degree in Mineral Processing in 2002. His master’s thesis focused on applying column flotation in the Sarcheshmeh Copper Complex, the largest copper mine in the Middle East. After his Master’s, he worked at the R&D centre of the Zarand coal washing plant in Iran for two years before becoming the plant manager. In 2007, he returned to the University of Kerman to pursue a PhD, investigating the effect of liner wear on charge motion and power draw of SAG mills, which he completed in 2010.

Since joining JKMRC in 2011, Mohsen has conducted extensive applied research and successfully delivered numerous industry-funded projects. As a comminution specialist, he is dedicated to implementing fundamental understandings in his research to offer practical solutions to the minerals industry and educate engineers and researchers with problem-solving skills for future resource industry challenges. His research focuses on optimising mineral processing techniques to enhance efficiency and sustainability, with a strong emphasis on practical application. Mohsen's research extends to advanced process control, including the development of soft sensors and model-predictive control solutions. His work aims to improve the precision and reliability of industrial processes, contributing significantly to the field of mineral processing.

Dr Ruifeng Yan (FIEAust, CPEng, NER, APEC Engineer, IntPE(Aus), RPEQ) received the B. Eng. (Hons.) degree in Automation from University of Science and Technology, Beijing, China, in 2004, the M. Eng degree in Electrical Engineering from the Australian National University, Canberra, Australia, in 2007 and PhD in Power and Energy Systems from the University of Queensland, Australia, in 2012. He was an ARC DECRA Fellow in the School of Electrical Engineering and Computer Science in the University of Queensland. His expertise includes renewable energy integration to power grids, big data mining in power systems, and network strength and stability analysis. He collaborates with power industries on a range of projects, including AEMO, Powerlink Queensland, Energy Queensland, EPEC Group, Siemens, Iberdorla Australia, Noja Power and Transgrid. He has published over 90 journal and conference papers, which have been cited by a number of top power utilities, national labs and academic institutes. He is currently served as an Associate Editor of the renowned IEEE Transactions on Power Systems, and an international Q1 journal – CSEE JPES. He also serves as a committee member in Engineers Australia Queensland Electrical Branch and CIGRE C4 Panel.

Dr. Zhe Yang currently is an ARC DECRA fellow in the School of Chemical Engineering/Dow Centre for Sustainable Engineering Innovation at the University of Queensland. He obtained his PhD degree in Environmental Engineering in 2018 at the University of Hong Kong (PhD supervisor: Prof. Chuyang Tang). He was appointed as research assistant/post-doc fellow in HKU from Nov 2018 to July 2021 and was further promoted to Research Assistant Professor from July 2021 to Dec 2023. He was recognized as a Top 1% Scholar worldwide ranked by Clarivate Analytics by citations in 2023. Dr. Yang has more than 10 years of R&D experience in membrane technology in the context of desalination, water reuse, and water/wastewater treatment. To date, he has published over 70 papers and two book chapters, with total citations of over 6,000 and an h-index of 42 based on Google Scholar. Most of these papers (90%) are published in Nature indexed/top tier journals in the field of environmental engineering and membrane technology, including Nature Communications, Nano Letters, Chemical Society Reviews, Environmental Science & Technology, Environmental Science & Technology Letters, Water Research, and Journal of Membrane Science. He has been awarded numerous prestigious awards, including The First Prize of the Water 2023 Young Investigator Award, Early Career Stars of Separation & Purification Technology, The 2022 ACS ES&T Engineering Best Paper Award, the Geneva International Exhibition of Inventions Gold Metal in 2019, etc. He currently serves as the Early Career Editorial Board member of the leading journal in his field (Desalination, IF 8.3).

Feature works:

1. Meta-analysis and establishing upper bound of reverse osmosis and nanofiltration membranes:

2023: His work on establishing the nanofiltration upper bound framework and investigating its impact on system performance (ACS ES&T Eng., 2, 3, (2021) 377-390) was awarded the 2022 ACS ES&T Engineering Best Paper Award.

2022: Based on the upper bound framework, Dr. Yang collaborated with several international researchers/teams from KU Leuven, Yale University, and Technion to develop an open-access database of TFC desalination membranes - Open Membrane Database (OMD) (J. Membr. Sci., 641 (2021) 119927).

2019: His work on establishing the upper bound correlation between permeance and selectivity for desalination membrane (J. Membr. Sci., 590 (2019) 117297) is the first top-cited papers published in the Journal of Membrane Science in the year 2019 and among the top 1% cited according to Essential Science Indicators (ESI Highly Cited Paper).

2. High-performance gutter layer-based reverse osmosis and nanofiltration membrane:

2017-now: His works on designing high-performance novel gutter layer-based reverse osmosis and nanofiltration membranes significantly advance the water permeance of conventional membranes by an order of magnitude with simultaneously improved selectivity, which successfully surpasses the permeance-selectivity upper bound. The significance of these studies is highlighted by several ESI Highly Cited Papers (Environ. Sci. Technol., 52 (2018) 9341-9349; Environ. Sci. Technol., 53 (2019) 5301-5308; Environ. Sci. Technol., 54 (2020) 11611-11621).

3. Mechanistic investigation of nanofiller-enhanced reverse osmosis membranes:

2019-now: In the membrane community, the concept of thin-film nanocomposite (TFN) has successfully led to several commercialized products including Aquaporin-containing TFN membranes by Aquaporin A/S1 and zeolite-based TFN seawater and brackish RO membranes by LG-Chem NanoH2O®. Nevertheless, the mechanisms for membrane performance enhancement remained unclear. Dr. Yang's works on TFN membranes (Environ. Sci. Technol., 53 (2019) 5301-5308; Environ. Sci. Technol. Lett., 7 (2020) 766-772) unveiled the underlying transport mechanisms of TFN membranes based on a systematic framework of the interior and exterior channels of the embedded nanofillers.

Professional memberships

1. A member of Membrane Society of Australasia (MSA), since May 2024

2. A member of Australia Water Association (AWA), since April 2024