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Prof. Amin Abbosh specializes in Medical Microwave Imaging and Microwave and Millimeter-wave Engineering. His work focuses on designing and developing advanced imaging and sensing systems using electromagnetic techniques at radio-wave frequencies.

Prof. Abbosh’s significant contributions include the creation of innovative imaging systems that leverage his expertise in applied electromagnetics and microwave engineering. He has developed comprehensive analytical and computational frameworks, incorporating signal-processing techniques for detection and AI for classification. This approach has led to a new modality for detection and imaging, combining physics-guided and data-driven methods. His work is protected by over 16 patents.

In Communication Technologies, Prof. Abbosh's work focuses on designing flat-panel, low-cost reconfigurable antennas. These antennas form ground satellite terminals that communicate with low-earth-orbit (LEO) satellites, providing reliable broadband access to remote and regional communities. This technology supports e-health services, distance education, and business productivity, and can be used in various on-the-move environments.

Recent News

August, 2019: Post Doctoral Researchers/Resercah Associates/PhD Candidates

A/Prof Abeyratne is accepting (2021) post-doctoral researchers/covering the areas of: pattern recognition, machine learning, respiratory sound analysis, digital signal processing and smart phone programming. Qualified students are invited to apply for PhD scholarships on a competitve basis.

June 2021:

Snore sound based Sleep Apnea diagnostics intellectual property developed by Dr. Udantha Abeyratne and his team are available for commercialisation. The technology is the culmination of 20 years of ground breaking work leading to four patent applications including two granted ones in the USA (the rest are under examination at various stages) and a large portfolio of peer reviewed publications in international scholarly journals. A Matlab implementation of re-trainable technology and performance comparions against American Academy of Sleep Medicine scoring critera of 2007 (AASM 2007) are available. Prior comparisons on Chicago Criteria ("AASM 1999") are also available via peer-reviewed literature. Our software models indicate that the technology can diagnose sleep apnea at a sensitivity and specificity approching that of a standard facility-based polysomnography (sensitivity, specificity around 90%, 90%-- cross validation studies). Note that the model development data sets available to us (n=100 approx) had been scored per AASM 2007 clinical criteria. Thus, the resulting models require a straight-forward re-training (re-calibration) process on AASM 2012 data before they can be used on subjects diagnosed under AASM 2012 criteria (which is the clinical scoring standard in effect since 2012).

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Assoc./Prof. Udantha Abeyratne is the inventor of the cough-sound based respiratory diagnosis technology (ResApp Health Ltd. (ASX: RAP)) and snore sound based sleep apnea diagnosis technology SnoreSounds.

He earned a PhD (Biomedical Engineering) from Drexel University, USA, and MEng and BScEE degrees in Electrical & Electronic Engineering from Tokushima U, Japan and U Peradeniya, (video here) Sri Lanka respectively. He also received formal post-graduate training in Higher Education (Grad Cert , U of Queensland, Australia) and Paediatric Sleep Science (Grad Cert., U of Western Australia, Australia). He is a Senior Member of the Institute of Electrical & Electronic Engineers (IEEE, USA), and a full Member of the American Academy of Sleep Medicine (AASM).

​Dr. Abeyratne started his research career with a paper on coding techniques for low-bandwidth communication channels. His master's thesis was on a machine learning approach to the human brain activity analysis using electroencephalography (EEG, Brain Waves) and evoked potentials. This approach won the best paper award in ISBET Brain Topography Conference (Osaka, Japan, 1990) and also placed Dr. Abeyratne as a finalist at the Young Investigators' Competition in IFMBE World Congress on Medical Physics and Biomedical Engineering, 1991 (Kyoto, Japan). He completed his PhD (1996) with Prof. Athina Petropulu as the advisor, working on Higher-Order-Spectra and medical ultrasound imaging. The thesis developed slice-based low-complexity algorithms for blind signal identification, tumor detection in ultarsound images, and image deconvolution.

Teaching Activities:

Assoc/Prof. Abeyratne has designed and taught university level courses on digital signal processing, electronic circuits, medical and general instrumentation, medical signal processing, medical imaging, control systems, project management and electromagnetic waves. He has supervised both undergraduate and postgraduate dissertation thesis projects in these areas. Within the last decade five students supervised by him won competitive awards at the UQ Innovation Expo.

Current Research Profile:

Assoc./Prof. Abeyratne's research interests encompass digital signal processing, machine learning, medical instrumentation, medical imaging, electrophysiology, bio-signal analysis and electronics. Over the last two decades A/Prof. Abeyratne has conceptualized, initiated and led the development of a number of innovative technologies funded by prestigious granting agencies such as the Bill & Melinda Gates Foundation, Australian Research Council and the A*-Star Singapore. His research programmes are characteristic of unorthodox approaches resulting in pioneering outcomes that produced spin-off companies, patents and scholarly publications. His research has recieved multiple peer accolades at the international level.

1. Electronic Instrument Design: hand-held ultrasound devices for medical, agricultural and industrial use; stethoscopes for the 21st century (The "Magithescope(c)", winner of two UQ Expo awards in 2013, 2014); biomimetic sensing devices (e.g. electronic nose, e-tongue), low-cost, portable electronic devices ("Tricoders") for diagnosing diseases such as apnea, asthma, pneumonia; wearable electrophysiological devices; real-time fatigue measurement and warning systems; hand-held instruments for the condition monitoring of machinery such as power transformers. Development of diagnostic and treatment devices for sleep apnea. Dr. Abeyratne is especially interested in developing accurate, multi-purpose and low-cost in-situ decision devices for applications in resource-poor regions of the world.

2. Diagnostic and Treatment Technology for Sleep Disorders: speech-like analysis of snore and breathing sounds; sleep diagnostic instrument design; sleep polysomnography, brain wave (EEG) analysis in sleep, quantification of fatigue and sleepiness; sleep apnea; design of apnea treatment devices (CPAP, dental devices); interaction of apnea and chronic diseases. mHealth approaches in sleep diagnostics. A/Prof. Abeyratne pioneered speech-like processing of respiratory sounds, leading to patents, papers and a spin-off company. He conceptualized and led the development of EEG based technology to quantifiy sleepiness in real-time in actual work environments. Outcomes of this program have recieved wide coverage in international media outlets due to its groundbreaking nature and the potential impact.

3. Respiratory Diagnostic Technology: diagnostic instrumentation and algorithm design for respiratory illnesses such as pneumonia, bronchiolitis, asthma, bronchiectasis and COPD; cough sound analysis in respiratory medicine; imaging technology for respiratory diagnosis; Portable diagnostic technologies and mHealth approaches for remote resource-poor areas of the world. About 1 million children below the age of 5 yrs die every year of pneumonia alone, mainly in remote resource-poor areas of the world. Poor access to diagnostics and medical treatment are the major reasons for pneumonia fatalities. A/Prof. Abeyratne proposed a ground-breaking new technology to diagnose pneumonia centred about cough sound analysis. For this research Dr. Abeyratne received funding from UQ, UniQuest and the Bill & Melinda Gates Foundation, which lauded the project (Page 4) as an exmaple for an innovative idea with high impact. Outcomes led to scholarly publications and contributed to patents as well as a spinoff company by UQ.

4. Signal Processing and Machine Intelligence: the analysis of bio-signals such as electroencephalography (EEG), electromyography (EMG); speech and industrial sound analysis, bowel sound analysis and the characterisation of inflammatory bowel disease; cardiovascular signal processing, source localization and blind source separation, higher order spectra, wavelets, pattern recognition, classifier design. Developing technology for monitoring the condition of Left Ventricular Assist Devices (LVAD).

5. mHealth: research on smart phone and other consumer devices as a platform for healthcare delivery. A/Prof Abeyratne is actively engaged in developing mHealth diagnostic solutions, including translating and customising sleep and respiratory technologies. He is also in the process of expanding the work to include meaningful deployment of the technology in both the developed and developing worlds, in collaboration with international NGOs, experts in community medicine, and the UQ spin-off companies resulting from the research program. New national and international collaborations are currently being negotiated to fund and facilitate this work.

The Research Team, Past & Present:

Associate professor Udantha Abeyratne, Dr. Keegan Kosasih (Past PhD graduate); Dr Duleep Herath (past PhD gradute, )Dr. Shahin Akhter (Past PhD graduate), Dr. Vinayak Swarnkar (Past PhD graduate ); Dr. Yusuf Amrulloh (Past PhD graduate); Dr. Shaminda de Silva (Past PhD graduate); Dr. Samantha Karunajeewa (Past PhD graduate); Dr. Suren Rathnayake (Past PhD graduate), Dr. Xiao Di (Past PhD graduate), Dr. T. Emoto (Past PhD work in UQ while at UT), ; Mrunal Markendeya (Current PhD Student); Karen McCloy (current PhD student), Ajith Wakwella (Past MPhil graduate); Lee Teck Hock (Past MPhil Graduate), Tang Xiaoyan (Past MPhil Graduate), Dr. Zhang Guanglan (Past MPhil Graduate), Dr. Syed Adnan (Past MPhil Graduate) and many past and present dissertation thesis students.

Research Collaborators:

Dr. Craig Hukins & Brett Duce (Princess Alexandra Hospital), Prof. Y. Kinouchi & Dr. T. Emoto (U of Tokushima, Japan), Dr. Sarah Biggs (Monash), Dr.Simon Smith (QUT), Dr. Chandima Ekanayake (Griffith U), Dr. Paul Porter (PMH Hospital), Prof. Anne Chang (Menzies School of Health Reserach, CDU), Dr. Scott Mckenzie (Princess Charles Hospital), Dr. Nirmal Weeresekera (JKMRC, UQ), Dr. Rina Triasih (Gadjah Mada U, Indonesia), Dr. K. Puvanendran (1998-2002: Singapore General Hospital, Singapore), Prof.Stanislaw Gubanski (Chalmers U, Sweden).

Dr Dia Adhikari Smith is the Tritium E-Mobility Research Fellow at The University of Queensland’s Dow Centre for Sustainable Engineering Innovation (School of Chemical Engineering) and the Transport Engineering Group (School of Civil Engineering). Her current research focusses on advancing the performance, economics, and uptake of E-Mobility globally, with a particular focus on the decarbonisation of both on-road and non-road heavy vehicles used in transport, construction, and mining sectors in Australia. Dia’s research expertise in low and zero emission heavy vehicles, powered by electric, hydrogen and advanced biofuels, has been demonstrated through several industry and government engagements to deliver decarbonisation feasibility studies, emissions modelling, cost benefit analyses, total cost of ownership scenarios and developing strategic roadmaps and recommended policy packages to achieve net zero emissions. Dia has a PhD in Power and Energy Systems Engineering from Glasgow Caledonian University, UK and worked as a Postdoctoral Fellow at the Centre for Integrated Renewable Energy Generation and Supply, Cardiff University, UK and as a Lecturer at the Grand Canyon University, Phoenix, USA.

Dia's postdoctoral research experience, at Cardiff University, involved in-depth research to investigate Smart Grid network assessment and planning methodologies that would consider type, extent, and pathway of various smart, innovative, and sustainable technology interventions (renewable energy sources, distributed generation, battery storage, electric vehicles, and hydrogen). Dia has worked on different quantitative and qualitative research methods to analyse the factors affecting the diffusion of low and zero emission technologies in the UK and conducted feasibility studies to evaluate the inhibiting factors for Smart Grid transition within the building industry (smart sustainable houses) and the mining sector (electric heavy vehicles, renewable energy sources, and energy storage) in the perspective of users, energy experts, energy providers, respective industries, policymakers, regulators, and the government. Dia's research projects involved close collaboration with Academia, Government and Industry to propose strategic guidelines, evaluate policies, and publish joint work-stream reports, for the successful diffusion of zero-emission technologies and renewable energy systems.

Dr. Yahia Ali serves as a research fellow and lecturer within the School of Mechanical and Mining Engineering at the University of Queensland, Australia. His primary research focus centers on applying scientific principles to address industrial challenges. He earned his PhD from the University of Queensland, while his MSc and BSc were obtained from the German University in Cairo. Throughout his career, he has amassed extensive expertise in areas such as alloy design, solidification, tribology of materials, and characterization techniques.

In conjunction with his academic responsibilities, Dr. Ali collaborates closely with the UQ Materials Performance (UQMP) consulting group. This interdisciplinary interaction between research and consulting significantly shapes his research direction, particularly in tackling industrial issues. As an illustration, Dr. Ali and his team have developed a distinctive range of devices for evaluating the performance of wear-resistant materials against abrasion and fracture. In Australia, Dr. Ali and his team holds a pivotal role in advancing the mining sector, providing innovative materials solutions, spanning from failure investigation to the development of novel materials. Through consecutive endeavors, they have influenced substantial business decisions for renowned companies like Rio-Tinto, Bradken, Molycop, IXL Metal Casting, Trelleborg, and others, often involving multi-million-dollar investments.

In 2023, Dr. Ali was honored as an Advance Queensland Industry Fellow, with a specific focus on developing sustainable alloys tailored for Queensland's agricultural and mining sectors. Additionally, he leads several projects concentrated on devising new testing techniques that can be conducted in the laboratory while preserving the authentic complexity of the industrial field environment.

Dr Mark C Allenby is a Senior Lecturer in Biomedical Engineering (2021-ongoing) and an ARC DECRA Fellow (2022-2025) within UQ's School of Chemical Engineering. Mark is also an Adjunct Senior Lecturer at QUT and previously an Advance Queensland Fellow (2019-2022). Mark has principally supervised 5 PhDs and 2 MPhil/RAs, co-supervised 7 PhDs, and has been awarded over $2.8M of funding as chief investigator across 20 competitive funding rounds in 4 years. Mark received a PhD and MSc in chemical engineering from Imperial College London, UK and bachelors degrees in mathematics and chemistry from Pepperdine University, USA. Mark's leadership is exhibited by the:

• 2024 ASBTE Emerging Leadership Award
• 2024 Friends of CCRM Australia Industry Advisory Network
• 2024, 2023, and 2022 Executive Board Member of ASBTE
• 2023 TERMIS-AP Young Investigator Award
• 2023 RegMedNet Rising Star Finalist
• 2020 QUT ECR Award

Research Interests: Mark leads the BioMimetic Systems Engineering (BMSE) Lab. In the BMSE Lab, we combine Tissue Engineering, Biomedical Image Analysis, and Computational Biology to study and solve biological and medical problems using advanced cell culture and computer models. Initially, we will focus on Systems of Blood, Blood Vessels, and Vascularised Tissue as these are essential building blocks for human and mammalian function. Our work aligns with bioprocess engineering fundamentals, cell therapy or medical device manufacturing, and clinical collaborators in haematology, vascular surgery, neurosurgery, and radiology. Our systems engineering approaches allow us to examine, computationally model, experimentally engineer, optimise, control, scale, and automate dynamic systems of several entities such as multi-cellular tissues or cell-material and cell-fluid systems.

Academic Interests: Mark is the Convener of UQ's Biomedical Engineering (BME) major, ranked #2 in Australia. BME at UQ spans schools of Chemical Engineering (ChE; #1 in Australia), Electrical Engineering, and Mechanical Engineering, and engages with UQ's Faculty of Medicine and associated healthcare services. Mark is part of ChE teaching and scholarship committees, and Mark acts as the academic advisor for ChE-BME undergraduates. Mark is the creator and coordinator of Quantitative Methods in Biomedical Engineering, and is a lecturer of Process Modeling & Dynamics. Mark has previously taught courses in biomaterials, process modelling, and reaction engineering in ChE and BME departments at three universities in the UK and Australia.

Our BMSE Lab is currently looking for excellent computational researchers. These include candidates and collaborators with experience in microscopy and medical image processing, cell population dynamics simulation, and/or biomechanics simulations (Python, MATLAB, R, ANSYS) to analyse high-content experimental data. Postdoc candidates are welcome to contact us to explore fellowship applications. Interested PhD and MPhil candidates should consider applying with us to the UQ Annual HDR Scholarship Round. We are always recruiting masters and undergraduate thesis project students for thesis projects advertised on our lab website.

Associate Professor Aminossadati completed BEng in 1989, MEng in 1994 and PhD in 1999 in the field of Mechanical Engineering. He is a highly accomplished academic with a wealth of experience in Mechanical and Mining engineering research and academia. He has made significant contributions to advancing collaborative research in this field and has gained national and international recognition for his research on flows in porous underground media thermofluids, flow simulations in pipes, pumps, turbines and compressors, fibre-optic sensing systems and underground mine ventilation systems. He has secured 16 research grants totalling $2,650,000, published 180 journal and conference papers, resulting in 2850 citations and an H-Index of 35. Additionally, he has produced 3 industry reports, served as academic advisor for 18 RHD students who have graduated and 8 current RHD students, and is a reviewer for 30 international journals. He has also been invited as a keynote speaker at the Mine Vent Conference in Brisbane in 2009 and the Fibre Optic Conference in China in 2015.

I am Group Leader of Bio-inspired Materials Research at the Australian Institute for Bioengineering and Nanotechnology, The University of Queensland. My pioneering research uses a nanocellulose platform technology to develop innovative materials for diverse applications, including biodegradable packaging materials, sustainable antimicrobial materials, protective medical textiles, and biocomposites. The application of nanocellulose for advanced materials is gaining interest internationally, and my vision is to capitalise on this momentum to spearhead research into new sustainable products that will have global impact.

I am a strong advocate for cultural diversity and equity and support staff and students to grow as more effective leaders and create social good.

In recognition of my contribution to the field of nanomaterials engineering and research excellence, I have received a number of awards including; The Eight Australian Women Who Are Shaking up the World Of Science (Marie Claire, 2020), one of Australia’s Top 5 Scientists (ABC/UNSW, 2018), Queensland Women in STEM Prize- judges choice award (2017), Women in Technology Life Sciences and/or Infotech Rising Star Award (2016), AIBN Research Excellence Award (2016), a Class of 2014 Future Leader award and Best poster prize at the Australian Nanotechnology Network ECR Entrepreneurship workshop(2015).

Dr. Pratheep Annamalai is a polymer and nanomaterials scientist with a keen interest in engineering materials for sustainable living. He is an Adjunct Senior Research Fellow at the School of Agriculture and Food Sciences. He has extensive expertise in both translational and fundamental research using nanotechnological tools towards sustainability. Currently, he is interested in alternative proteins and valorisation of agricultural crops and food waste into reactive, building blocks for improving the performance and utility of bioproducts. Thematically, his research focuses on

• Food Processing (plant-based food products)
• Bioproducts (from agri-food waste)
• Sustainable building blocks (for advanced materials).

Before joining UQ, Pratheep studied Chemistry in University of Madras, received PhD in Chemistry from University of Pune (India), then went on to work as a postdoctoral researcher on hydrophobic membranes at the Université Montpellier II (France), and on ‘stimuli-responsive smart materials’ at the Adolphe Merkle Institute - Université de Fribourg (Switzerland).

Upon being instrumental in the discovery of ‘spinifex nanofibre nanotechnology’ and establishing Australia’s first nanocellulose pilot-plant, he has been awarded UQ Excellence awards for leadership and industry partnerships for 2019. Recognising his contribution to the nanomaterials, polymer nanocomposites, polymer degradation and stabilisation regionally and globally, he has been invited to serve as a committee member for ISO/TC229-WG2 for characterisation of nanomaterials (2016), a mentor in TAPPI mentoring program (2018), guest/academic editor for various journals (Fibres, Int. J Polymer Science, PLOS One). He has served as a member of the UQ-LNR ethics committee for reviewing the applications (2017-) and a member of the AIBN-ECR committee in 2014.

Nigel is public health and health services researcher with interests and expertise in quantitative research methods, epidemiology, evidence-based health care, clinical trials, and digital health. He is a member of the Improving health outcomes after musculoskeletal injury group at the RECOVER Injury Research Centre, and is a chief investigator of the NHMRC Centre for Research Excellence in Better Outcomes for Compensable Injury. His work focusses on the epidemiology and burden of minor to moderate injuries, longitudinal data analyses of intervention trial data, population studies of health-related quality of life and chronic pain, and the potential of digital heath for assessment and intervention following injury.

Nigel has particular interests in new innovations in healthcare, and has previously worked in minimally-invasive surgical trials in gynaecology, and clinical trials assessing the feasibility, efficacy and effectiveness of clinical telemedicine in paediatric healthcare. His doctorate work (Awarded 2011, UQ School of Medicine) involved the design, development, and clinical/cost/acceptability evaluation of real-time telemedicine for acute consultation between a tertiary neonatal intensive care unit and four peripheral referring hospitals in Queensland. He maintains an active research interest in telemedicine, and more broadly in digital health. Between 2004 and 2015, Nigel was involved in the telepaediatric service at the Royal Children's, and the Lady Cilento Children's hospitals in Brisbane where he also co-ordinated an Indigenous Ear Health Screening Program. He is an associate editor of the Journal of Telemedicine and Telecare and an academic editor for PLOS ONE.

Nigel regularly participates in national and international grant review panels, and is an active HDR and occupational-trainee supervisor. He is a Fellow of the Royal Society of Medicine and the Royal Society for Public Health (FRSPH), a member of the Australian Epidemiological Association (AEA), International Epidemiological Association (IEA), the International Association for the Study of Pain (IASP), the Association for Interdisciplinary Meta-Research and Open Science (AIMOS), and is a qualified Justice of the Peace, JP (qual).

Prof Andrej Atrens's research interests are in: the service performance of engineering materials and alloy development.

He received a PhD from the University of Adelaide in 1976, a DEng from the University of Queensland in 1997, and became FHEA in 2018.

His current research projects are in the fields of:

• Mg Corrosion
• SCC
• Hydrogen embrittlement

Experienced materials engineering researcher with proven experience in developing chemically tuned structures for commercial opportunities. My unique skill set spans interfacing technical analysis (morphology, composition, performance, and durability) of sustainable composite materials with economic feasibility and quality system requirements from research and industry associates. I am a team player, and the guiding principles by which I function in all facets of my life include ‘shared values’, ‘shared vision’, ‘complementary expertise’ and ‘diligence’.

Feifei Bai is a Senior Lecturer with the School of Electrical Engineering and Computer Science at the University of Queensland, Australia. She is also an adjunct Senior Reserach Fellow at Griffith University. She was awarded the Advance Queensland Fellow in 2018. Her research contributions can be recognised by a strong publication record, delivered over $2.7 million research projects, patent commercialisation, and research outcome implementation by the industry. She serves as a guest associate editor for the special issue “Flexible and Resilient Urban Energy Systems” of the International Journal of Electrical Power & Energy Systems in 2021. She is an associate editor for the journal of IET Generation, Transmission & Distribution and an assistant editor for the International Journal of Green Energy. She also actively collaborates with Australian industries including Energy Queensland, NOJA Power, Powerlink, AEMO, and EPEC Group. One ARENA project in which she was a key researcher received an Australian Engineering Excellence Award in 2020.

Lisa Bai is a Postdoctoral Research Fellow in the Australian Centre for Water and Environmental Biotechnology at the University of Queensland, where she is involved in a range of research projects on process development for sustaibale waste and wastewater management. Her main research focus is resource recoverying from waste and wastewater for the production of bioenergy sources and value-added materials such as biodegradable plastics.

Dr. Bai obtained her Bachelor Degree in Bioengineering in Central South University, China and a PhD degree in the School of Chemical Engineering at the University of Queensland. Both her bachelor and PhD thesises were focusing on open culture microalgae mass production as well as product, nutrients and energy recovery from the biomass. Before joining ACWEB, Lisa worked in an environmental service company in North Queensland (Townsville - Bowen) for four years, focusing on process design and development for the aquaculture water bioremediation using macroalgae technologies and utilising waste streams as feedstocks for the production of biomass for a diverse usage including aquaculture feed, fertiliser, and other bioactive compound.

Dr. Baldelli joined the School of Agriculture and Food Sustainability and the Queensland Alliance for Agriculture and Agriculture and Food Innovation (QAAFI) in 2024 as a Senior Lecturer. He achieved his PhD from the University of Alberta in Particle Engineering; after that, he obtained a Postdoctoral Fellowship and a Research Fellowship at the Faculty of Food and Land Systems at the University of British Columbia.

Dr. Baldelli's research areas of interest are Particle Engineering, Food Technology, Spray Drying, Encapsulation of Bioactive Compounds, Spray Coatings, Food Fortification, Nasal Delivery, and Dry powders.

Professor Tom Baldock, B.Eng, Ph.D (Lond), DIC, MIEAust.

****Ph.D. Scholarships in Coastal and Marine Engineering, School of Civil Engineering, University of Queensland, Australia****

Please enquire about forthcoming UQ scholarship opportunities for domestic Australian students (citizens or permanent residents) or international students who are currently in Australia.

Ph.D. projects are available on coastal processes, coral reef hydrodynamics, tsunami impacts, wave energy or a topic of your own

Professor Baldock’s research is primarily in the field of Coastal and Ocean Engineering, but also encompasses renewable energy and higher education. He has published over 120 journal papers and over 80 conference papers, notably in top-rated journals for his discipline (Journal of Fluid Mechanics, Proceedings and Transactions of the Royal Society), and is the most published author in the journal Coastal Engineering over the past decade. He is presently principal supervisor for 6 Ph.D. students, with 18 PhD students graduated since 2007, three of whom were awarded Dean’s awards, and nine have secured T&R or research positions nationally and internationally, one a full Professor. His Ph.D. students have published over 60 journal papers since 2004. They have worked on field and laboratory experiments in the UK, Europe, the USA, in association with international researchers and government agencies. Prof Baldock received a UQ Award for “Excellence in HDR Supervision” in 2017. He is currently working on a major project within the National Reef Restoration and Adaption Program (https://gbrrestoration.org/) focused on the Great Barier Reef.

He has strong national and international collaboration on research on topical issues in coastal engineering and close links with Government and National agencies, which includes consultancy and expert witness services in Marine Engineering. Recent and current relevant research projects include a multi-partner CSIRO Cluster project under the Wealth from Oceans Flagship, investigating tsunami impact on ultra-long submarine pipelines running from the deep ocean up to continental slope and then onshore, ARC Discovery, ARC Linkage and ARC LIEF projects investigating storm surge and wave run-up along the East Australian coast, and four European Union HYDRALAB IV transnational access projects to study beach erosion and recovery processes in large wave flume facilities. He is also working with Geoscience Australia on the Bushfire and Natural Hazards projects, Resilience of Coasts to Clustered storm events and with the Global Change Institute (UQ) on the World Bank project "Capturing Coral Reef Ecosystems Services".

He is a member of the Editorial Board for Coastal Engineering and a member of the Engineers Australia National Committee on Coastal and Ocean Engineering.

He was Chair of the Organising Committee for Coasts and Ports 2017, held in Cairns, June 2017

His primary research interests are in : Swash zone hydrodynamics, Beach face sediment transport, Coral reef hydrodynamics and associated shoreline behaviour, Long wave generation and surf beat, Extreme non-linear waves (freak waves), Storm surge and tsunami hazards.

His current research projects are in the fields of:

1. Swash Zone hydrodynamics and Sediment Transport
2. Wave overtopping, including tsunami overtopping
3. Coral reef hydrodynamics
4. Impact of sea level rise on coastlines on open and reef-fronted coasts
5. Surf zone processes and beach erosion
6. Infrastructure for offshore aquaculture
7. Wave energy conversion

Google Scholar : https://scholar.google.com.au/citations?hl=en&user=QU14lwEAAAAJ

Top publications

Baldock, T.E., Swan, C. and Taylor, P.H., 1996. A laboratory study of non-linear surface waves on water. Philosophical Transactions of the Royal Society, London, Series A. 354, 1-28. [ERA – A]

Baldock, T. E and Huntley, D. A., 2002. Long wave forcing by the breaking of random gravity waves on a beach. Proceedings of the Royal Society, London, Series A. 458, 2177-2201. [ERA – A*]

Baldock, T.E., 2006. Long wave generation by the shoaling and breaking of transient wave groups on a beach, Proceedings of the Royal Society, London., Series A. 462, 1853–1876. [ERA – A*]

Baldock, T. E., O’ Hare, T. J., and Huntley, D. A.., 2004. Long wave forcing on a barred beach. J. Fluid Mechanics, 503, 321-341. [ERA – A*]

Pritchard, D., Guard, P.A. and Baldock, T.E., 2008. An analytical model for bore-driven run-up. Journal of Fluid Mechanics, 610: 183-193. [ERA – A*]

Baldock, T.E., Peiris, D. and Hogg, A.J., 2012. Overtopping of solitary waves and solitary bores on a plane beach. Proceedings of the Royal Society, London, Series A., doi: 10.1098/rspa.2011.0729. [ERA –A*]

Saunders, M.I. et al., 2014. Interdependency of tropical marine ecosystems in response to climate change. Nature Clim. Change, 4(8): 724-729. [ERA – A*]

Latest publications:

1. Lancaster, O., Cossu, R., Wilson, M., & Baldock, T. E. (2022). A 3D numerical and experimental parametric study of wave-induced scour around large bluff body structures. Ocean Engineering, 112766. doi:https://doi.org/10.1016/j.oceaneng.2022.112766
2. Astorga-Moar, A., & Baldock, T. E. (2022). Assessment and optimisation of runup formulae for beaches fronted by fringing reefs based on physical experiments. Coastal Engineering, 176, 104163. doi:https://doi.org/10.1016/j.coastaleng.2022.104163
3. Thompson, M. E., Matson, B. J., & Baldock, T. E. (2022). A globally verified coastal glare estimation tool. Coastal Engineering, 177, 104190.
4. Shabani, B., Ware, P. & Baldock, T. E. 2022. Suppression of Wind Waves in the Presence of Swell: A Physical Modeling Study. Journal of Geophysical Research: Oceans, 127, e2021JC018306.
5. Lancaster, O., Cossu, R., Wuppukondur, A., Astorga Moar, A., Hunter, S., & Baldock, T. E. (2022). Experimental measurements of wave-induced scour around a scaled gravity-based Oscillating Water Column Wave Energy Converter. Applied Ocean Research, 126, 103268. doi:https://doi.org/10.1016/j.apor.2022.103268
6. Wuppukondur, A. and Baldock, T.E., 2022. Physical and numerical modelling of representative tsunami waves propagating and overtopping in converging channels. Coastal Engineering, p.104120.
7. Wiegerink, J. J., Baldock, T. E., Callaghan, D. P. & Wang, C. M. 2022. Slosh Suppression Blocks - A concept for mitigating fluid motions in floating closed containment fish pen in high energy environments. Applied Ocean Research, 120, 103068.
8. Lancaster, O., Cossu, R., Heatherington, C., Hunter, S. & Baldock, T. E. 2022. Field Observations of Scour Behavior around an Oscillating Water Column Wave Energy Converter. Journal of Marine Science and Engineering, 10, 320.
9. Blenkinsopp, C. E., Baldock, T. E., Bayle, P. M., Foss, O., Almeida, L. P. & Schimmels, S. 2022. Remote Sensing of Wave Overtopping on Dynamic Coastal Structures. Remote Sensing, 14, 513.
10. Ibrahim, M. S. I. & Baldock, T. E. 2021. Physical and Numerical Modeling of Wave-by-Wave Overtopping along a Truncated Plane Beach. Journal of Waterway, Port, Coastal, and Ocean Engineering, 147, 04021025.
11. Thompson, M., Zelich, I., Watterson, E. & Baldock, T. E. 2021. Wave Peel Tracking: A New Approach for Assessing Surf Amenity and Analysis of Breaking Waves. Remote Sensing, 13, 3372.
12. Birrien, F. & Baldock, T. 2021. A Coupled Hydrodynamic-Equilibrium Type Beach Profile Evolution Model. Journal of Marine Science and Engineering, 9, 353.
13. Lancaster, O., Cossu, R., Boulay, S., Hunter, S. & Baldock, T. E. 2021. Comparative Wave Measurements at a Wave Energy Site with a Recently Developed Low-Cost Wave Buoy (Spotter), ADCP, and Pressure Loggers. Journal of Atmospheric and Oceanic Technology, 38, 1019-1033
14. Baldock, T.E., Gravois, U., Callaghan, D.P., Davies, G. and Nichol, S., 2021. Methodology for Estimating return intervals for storm demand and dune recession by clustered and non-clustered morphological events. Coastal Engineering, p.103924.
15. Bayle, P.M., Beuzen, T., Blenkinsopp, C.E., Baldock, T.E. and Turner, I.L., 2021. A new approach for scaling beach profile evolution and sediment transport rates in distorted laboratory models. Coastal Engineering, 163, p.103794.
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I am an academic paediatric neurologist, clinical researcher, and specialist in acquired brain injury in children and adolescence. I studied at the University of Edinburgh and British Columbia before taking up my first academic position at the University of Calgary in 2002. Here I developed and directed the Traumatic Brain Injury and Concussion Research Program at the Alberta Children's Hospital and where I cemented my interest in the biology and treatment of children with brain injuries. I have extensive clinical research experience, devising and overseeing clinical trials in children both nationally and internationally. I moved to the Child Health Research Centre at the University of Queensland, Australia in October 2017 and joined the Queensland Paediatric Rehabilitation Service and Queensland Cerebral Palsy Rehabililation Centre to facilitate research into improving the health outcomes of children with acquired brain injury in Queensland and Australia.

My research focuses on the neurobiological signatures and treatment of subtle neurological dysfunction in mild traumatic brain injury and concussion, especially the behavioural and cognitive impairments that are found in post-concussion syndrome. I use multimodal neurological assessments to do this. My research explores combining neuroimaging and neurophysiological investigations, including perfusion studies using MRI (ASL-fMRI) and transcranial magnetic stimulation to help us understand the changes in the brain in children who are slow to recovery following a concussion. This is to help us develop and assess more effective and tailored treatments for children with concussion and traumatic brain injury. I explore novel therapies for children with persistent post-concussive symptoms in clinical trials including the use of neuraceuticals, pharmacotherapies, and non-invasive brain stimulation treatment.

I am the director of the newly-established KidStim Lab at the Child Health Research Centre. This is the first non-invasive neuromodulation facility aimed at improving the health outcomes of children with brain injury in Australia and is led by a mulitdisciplinary team of clinicians and scientists from Brisbane bring a unique clinical and scientific knowledge-base to help achieve our goals. Rehabilitation therapy in combination with repetitive transcranial direct current stimulation (rTMS) and other direct current stimulation modalities (e.g. tDCS) will be explored. It also offers the potential for treatment of the mood and behavioural disorders (e.g. depression and anxiety) commonly seen after brain injury but also so disruptive to the life of the normally developing teenager.

Markus graduated from the Vienna University of Technology in Technical Physics in 1995 and was awarded his Doctorate in 1999 after which he worked as postdoctoral research associate and then Assistant Professor at the Department of Radiodiagnostics, Medical University Vienna (AT). From 2004 he worked as Senior Researcher at the Donders Institute for Brain, Cognition and Behaviour (Radboud University Nijmegen, NL) and at the Erwin L. Hahn Institute for Magnetic Resonance Imaging (University Essen-Duisburg, DE). In 2014 he relocated to the University of Queensland to head the Ultra-high Field Human MR Research program at the Centre for Advanced Imaging and was awarded an ARC Future Fellowship. In 2019 he joined the School of Information Technology and Electrical Engineering as Full Professor MR Physics and Medical Imaging and has been appointed as Director for the National Imaging Facility – Queensland Node.

Prof. Damien Batstone is Director of the Australian Centre for Water and Environmental Biotechnology, where he leads environmental biotechnology and resource recovery research programmes. His research work has focused on renewable energy from biomass, production of commodity chemicals from renewable sources, and the water-energy-food nexus, including production of novel chemicals and feeds for aquaculture from gases such as hydrogen.

Anaerobic and Environmental Biotechnology

Our group specialises in processes which use anaerobic (or without air) conversions to produce bioenergy, green electricity, and other high-value products from wastes and other low value feeds.