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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.
16. Blenkinsopp, C.E., Bayle, P.M., Conley, D.C., Masselink, G., Gulson, E., Kelly, I., Almar, R., Turner, I.L., Baldock, T.E., Beuzen, T. and McCall, R.T., 2021. High-resolution, large-scale laboratory measurements of a sandy beach and dynamic cobble berm revetment. Scientific data, 8(1), pp.1-11.

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

Remo has over 15 years of research experience in water engineering and joined the School of Civil Engineering in February 2016. Remo’s research projects span over a range of topics such as marine renewable energy, hydrodynamics in coastal areas, sediment transport processes, seafloor mapping and environmental engineering.

Remo started his professional career as a Research Associate at the Franzius-Institute for Hydraulic, Waterways and Coastal Engineering at Hannover University, Germany. Remo did his PhD on the hydrodynamics of oceanic gravity and turbidity currents under the influence of Coriolis forces in the Earth Sciences Department, University of Toronto, Canada. He continued his work in Canada as a Postdoctoral Fellow in the Department of Physical and Environmental Sciences at the University of Toronto where he focused on turbulence in coastal boundary layers and sediment transport processes in density currents. Before joining UQ, Remo was working as a Lecturer and Postdoctoral Fellow at the Australian Maritime College (AMC) at the University of Tasmania where he worked on projects in Tasmanian coastal waters (renewable energy, analysis of tidal currents, pipeline surveys) and limnological processes (Lake Ohau, New Zealand). A career highlight was a research trip with a team of sea-ice experts funded by NZARI to Antarctica (Cape Evans, McMurdo Sound) to analyze characteristics of the sea-ice ocean boundary layer using an autonomous underwater vehicle (UBC Gavia AUV).

Remo’s research over the last years has created advances in renewable energy site exploration methods that aims to fill a critical knowledge gap in understanding the suitability of candidate sites and linking local conditions (hydrodynamics, geotechnical aspects) with device design. Remo is involved as a lead researcher on several projects, for instance, the AUSTEn project for tidal energy exploration in Australian coastal waters (http://austen.org.au/) and the recently funded Blue Economy CRC (https://blueeconomycrc.com.au/).

My research career began when I recognised that the marine world has a history and pattern that can be studied to better explain the past, understand the present, and predict the future. I started studying beaches and coral reefs since they are iconic and complex systems where marine, ecological, geological and human processes interact to produce the ecosystems we see today. My goal, and that of my lab (The BeachLab), is to develop tools, gather data, and provide analyses to help coastlines and coral reefs navigate a warmer world. Our projects are focused on fundamental research questions about how coasts and coral reefs change through time. We also have applied research objectives to support the future management of coastal and coral reef systems.

I am now a teacher and researcher in Geography and Marine Science at the School of the Environment at UQ. Prior to my appointment at UQ, I was a teacher and researcher at The University of Sydney (where I completed my Undergraduate and PhD) and in a combined post at The University of Bremen (MARUM) and the Leibniz Center for Tropical Marine Ecology (ZMT). Perhaps equally importantly I grew up on the east coast of Australia and I have a personal and professional passion for beaches, coral reefs, surf, and the ocean.

BSc.Hons. (HKU), MPhil. (HKU), PhD (NUS)

Dr Annie Lau is a coastal geomorphologist with a primary research interest in analysing past occurrences of coastal hazards, in particular extreme waves generated by storms and tsunamis, through sedimentary, geomorphological and historical records for assessing the future threat in coastal areas. For example, she has specialised in using the characteristics of large coastal boulders (e.g. size and distribution of rocks) to estimate the strength of extreme waves and to reconstruct the history of extreme events in the past millennia at a few tropical islands in the Asia-Pacific area. More recently, Annie investigates coastline evolution of the sandy Central to Southern Queensland coasts in the late Quaternary - Holocene by analysing sediments and using OSL quartz dating.

Annie teaches a range of courses in Geography, Marine Science, and Geoscience disciplines. She is interested in all types of natural hazards and disaster management, some research areas that she's expanding into since acquiring in-depth knowledge through leading the "Environmental Hazards" course. Students who are interested in researching hazard topics are encouraged to discuss their research ideas with Annie.

She is a project leader of the following research networks:

IGCP Project 725 - Forecasting Coastal Change: "From Cores to Code: Bringing together scientists from coastal geology and numerical modelling to improve the predictive capacity of numerical models to fore- and hind-cast coastal change"

ISROC - Inundation Signatures on Rocky Coastlines: This network serves as a focal point for researchers, educators, and students to understand Coastal Boulder Deposits (CBD) and the storms and tsunamis that generate them.

Research interest: Monitoring ecosystem health of coral reefs and seagrass habitats, integrating field and remote sensing image datasets, and the developing applied cost-effective mapping and monitoring approaches. Developed approaches have been adopted as standard practice globally, making a difference in conservation of these valuable habitats. The long term monitoring studies at Heron and Moreton Bay formed the basis for the development of mapping and monitoring over time and space at local to global scale.

Current projects:

1) Long term monitoring of benthic composition at Heron Reef (2002-ongoing). Annual photoquadrate surveys are being collected at Heron Reef, Southern Great Barrier Reef. Initiated to develop remote sensing mapping approaches and assess coral composition over time. The resulting Maps, photo quadrate and benthic data, spectral reflectance are accessible online.

2) Long term monitoring of seagrass composition and abundance in Moreton bay Marine Park (2000-ongoing). For Eastern Banks it included monitoring seagrass species, cover and biomass 15x times since 2004 using photoquadrate survey and satelite imagery and for Moreton Bay it included seagrass extent and cover (2004, 2009, 2015, 2021, 2022), all data accessible via Moreton Bay Research Station.

3) Smart Sat CRC Hyperspectral Remote Sensing of Seagrass and Coral Reefs 2023-2027. Collaborative effort with CSIRO, Adelaide University, DES Adelaide Coastal Waters.

4) 3D GBR Habitat Mapping Project 2015 - ongoing: Mapping and monitoring geomorphic zonation, bottom type and predicted coral type habitat for every Great Barrier Reef within the Marine Park.

5) Global habitat mapping project 2019-2023 Developed and implemention of global habitat mapping as part of the Allen Coral Atlas resulting in extent, geomorphic and benthic maps for reefs globally, funded through with Vulcan Philanthropies in partnership with; Planet; the Arizona State University and the National Geographic Society.

Other projects: Advisor for Reef Cloud Australian Institute of Marine Science and Coordinated Global Research Assessment of Seagrass System (C-GRASS).

Current position: Associate Professior in Marine Remote Sensing. Academic Director Heron Island Research Station and affiliated researchers with Centre for Marine Science and Centre for Biodiversity and Conservation Science

Capacity building: under/post graduate courses; Msc/PhD supervision, workshops/courses; Remote Sensing Educational Toolkit, and online courses (e.g. TNC)

Citizen science: Strong supporter of citizen science based projects, as trainer, organiser and advisor for Reef Check Australia, CoralWatch, Great Reef Census and UniDive.