1 October 2019
Dr Thomas Moore
CSIRO RV Investigator. CSIRO Australia
Our RV Investigator leaves the shelter of Moreton Bay, steaming for the core of the East Australian Current. Photo: Dr Thomas Moore
Australia is an ocean nation – we’re girt by 10 million square kilometres of water. Whether you live near the coast or far from the shore, there’s no doubt the oceans are central to your life. From our weather and climate, to our food and energy, right down to our overall lifestyle and wellbeing.
But much of our surrounding ocean and our four major currents, including the East Australian Current (EAC) remain a mystery. Therefore, scientists are getting out there to see what it’s all about.
Deepening our understanding of these colossal currents is core business for the Integrated Marine Observing System (IMOS) and its Deep Water Moorings Facility, led by our very own Dr Bernadette Sloyan.
Wait – what exactly is the EAC?
Bernadette and her science and engineering team have been continuously observing a key slice of the EAC since 2015. We chatted to the Bernadette to break down what the EAC is all about. She’s just returned from a three-week voyage aboard our research vessel Investigator in the Coral Sea.
“The EAC is the largest ocean feature off Australia’s east coast,” Bernadette said.
“Changes in the EAC just beyond our beaches impact our coastal industries and communities. Over in Australia’s regional and rural centres, life beats to a drum of climate conditions that is partly influenced by our dynamic ocean and its relationship with the atmosphere.”
From Queensland to Tasmania, the powerful EAC is up to 100 kilometres wide, 1.5 kilometres deep. And it can carry up to 40 million cubic metres of water each second. That’s 70 billion pint glasses, refilled at sixty times a minute – it’s HUGE!
Bernadette explained that the EAC serves an important role beyond its powerful flow.
“It also acts as a kind of salty delivery van. Transporting warm water and nutrients that fertilise our ocean ecosystems,” she said.
“The EAC is also very fickle, hugging the coast one day and then flowing hundreds of kilometres out to sea the next. This unstable behaviour renews fish stocks, impacts water quality and weather, and sets the water temperature for swimmers and surfers.”
Dr Bernadette Sloyan, a Chief Research Scientist with our Oceans and Atmosphere team and leader of the IMOS Australian Bluewater Observing System facility, explains her voyage plans to Drs Océane Richet and Violaine Pellichero. Photo: Dr Thomas Moore
Keeping tabs on the EAC
In order to monitor how the EAC is changing over time, we use an array of deep-water moorings.
Deep water mooring at Totten Glacier. Image credit: Steve Rintoul, CSIRO and ACE CRC.
Consequently, IMOS has established a network of advanced marine equipment that tracks changes in the EAC. It’s currently lined up, across and down the slope of seabed near Moreton Bay, Queensland. This underwater observatory continuously monitors the EAC’s complex and highly energetic nature, discovering links to changes in our climate and coastal ecosystems.
But, nothing lasts forever. Like a new smartphone, their advanced sensors and tiny computers working away under the waves need to be recharged. As a result, the mooring’s “batteries” go flat about every year and a half.
The good news is that Bernadette and her team recovered the six deep-water moorings on this latest voyage. They boosted their batteries, downloaded their data, and have put the gear back to work for Australian science.
Blue-water deck work is a unique and critical capability of CSIRO’s Mooring Sensor Systems team. Jamie Derrick directs the winch driver as a syntactic float with current sensor is recovered from the ocean. Photo: Dr Thomas Moore
Biologists and oceanographers, unite!
Our oceanographers were also accompanied on board by biological specialists – collaborators from both University of New South Wales and Griffith University.
The ecologists were exploring how the EAC and ocean eddies (big ocean whirlpools) that weave their way through it can support abundant and diverse communities of larval fish and sea jellies.
Paloma, one of the ecologists, examines larval fish. The IMOS Larval Fish & Deep Water Mooring programs link ocean physics to ecosystems driven by a dynamic East Australian Current.
The voyagers deployed scientific equipment and net systems off Investigator in order to sample the ecology of this ever-changing region off the shore of Brisbane.
This cooperation between ocean physics and marine biology boffins will help connect the dots between the apparent chaos of a mammoth ocean current and its often-unappreciated impact on our lives.
See the full article here .
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Please help promote STEM in your local schools.
SKA/ASKAP radio telescope at the Murchison Radio-astronomy Observatory (MRO) in Mid West region of Western Australia
So what can we expect these new radio projects to discover? We have no idea, but history tells us that they are almost certain to deliver some major surprises.
Making these new discoveries may not be so simple. Gone are the days when astronomers could just notice something odd as they browse their tables and graphs.
Nowadays, astronomers are more likely to be distilling their answers from carefully-posed queries to databases containing petabytes of data. Human brains are just not up to the job of making unexpected discoveries in these circumstances, and instead we will need to develop “learning machines” to help us discover the unexpected.
With the right tools and careful insight, who knows what we might find.
CSIRO, the Commonwealth Scientific and Industrial Research Organisation, is Australia’s national science agency and one of the largest and most diverse research agencies in the world.
