River systems hold information on tectonic history in their sediment load and their morphology.
Coupled models of tectonics, topography and surface evolution help us to understand continental deformation patterns.
This project uses state-of-the-art tools in models of collision, basin formation and plate boundaries.

The recent over-ice seismic deployments in Antarctica provide datasets that enable exciting opportunities for seismological research. This project involves innovative development in passive seismology methods adapted for challenging icy conditions to unravel ice and solid Earth structure in Antarctica.

Some of the oldest continental building blocks (e.g. cratons) are found in Australia. At depth, the ancient rock record has invaluable information about the dynamics of the Earth. Seismology can provide remarkable views into the deep lithospheric structure using imaging techniques on broadband seismic data.

Grow organisms in aquaculture and explore how they grow their shells and record environmental conditions using a range of microanalysis and epifluoresence methods

These projects aim to monitor how environmental processes change chemistry and mineralogy both in the field and in lab simulations using spectroscopy. The projects can be adjusted for different levels of students.

Using Porites coral cores to examine elemental and isotopic proxies to develop proxy reconstructions of the environment.

This research program uses laboratory experiments and geophysical imaging techniques to constrain the thickness and density structure of continental crust and investigate its relationship to mineral systems.

Utilize elemental, isotopic and radiometric proxies trapped in deep sea coral skeletons to examine past climate.

Developing ultra-green hydrogen technologies

Congested subduction happens whenever buoyant material such as an oceanic plateau gets caught up on a moving plate and eventually arrives at a subduction zone. The buoyant material may be scraped off or subducted, but it always puts up a fight which leaves characteristic scars on the over-riding plate.

Most of Earth’s volcanism is concentrated at tectonic plate boundaries, where plates move away from one another to create mid-ocean ridges, or where one plate slides beneath another to form a subduction zone. However, an important and widespread class of volcanism occurs within plates, or across plate boundaries....

The objective of this ARC Linkage project with Geoscience Australia and GSWA is to provide a compilation of 3-D models of the crustal and lithospheric structure from new broadband data obtained with deployment of 25 seismometers in Southwest WA.

The W-phase is a ultra-long period seismic wave that arrives as early as the first-arriving P-wave. It’s early arrival, low amplitude and stability w.r.t. details of earth structure make it ideal for rapid determination of source characteristics especially for large, tsunamigenic earthquakes. We are exploring the...

The Himalaya are the world’s largest mountain belt formed in response to Cenozoic collision of the Indian continent & the Eurasian plate. This project assesses uplift history of the Himalaya, its erosional landscape response, & the preservation potential of critical mineral systems in this region.

The lowermost mantle sits atop the core-mantle boundary – the most dramatic boundary within our planet, with contrasts in physical properties that exceed those that exist at the surface. Despite significant progress, this region is not well understood, and global seismology paves the path towards new understanding.