James Cook University, University of Sydney and Queensland University of Technology scientists working with laser data from the Royal Australian Navy have discovered a vast reef behind the familiar Great Barrier Reef.
JCU’s Dr Robin Beaman says the high-resolution seafloor data provided by LiDAR-equipped aircraft have revealed great fields of unusual donut-shaped circular mounds, each 200-300 metres across and up to 10 metres deep at the centre.
“We’ve known about these geological structures in the northern Great Barrier Reef since the 1970s and 80s, but never before has the true nature of their shape, size and vast scale been revealed,” he said.
Dr Beaman said it was an astounding revelation. “The deeper seafloor behind the familiar coral reefs amazed us.”
The fields of circular donut-shaped rings are Halimeda bioherms, large reef-like geological structures formed by the growth of Halimeda, a common green algae composed of living calcified segments.
These form small limestone flakes on death, looking much like white cornflakes. Over time these flakes build up into large reef-like mounds, or bioherms.
Mardi McNeil from Queensland University of Technology and lead author on the new research paper, said their extent is vast.
“We’ve now mapped over 6000 square kilometres. That’s three times the previously estimated size, spanning from the Torres Strait to just north of Port Douglas. They clearly form a significant inter-reef habitat which covers an area greater than the adjacent coral reefs.”
Associate Professor Jody Webster from the University of Sydney, said the revelations about the extent of the bioherm field make questions over its vulnerability to climate change even more pressing.
“As a calcifying organism, Halimeda may be susceptible to ocean acidification and warming. Have the Halimeda bioherms been impacted, and if so to what extent?”
Dr Beaman said the discovery also opened up many other new avenues of research.
“For instance, what do the 10-20 metre thick sediments of the bioherms tell us about past climate and environmental change on the Great Barrier Reef over this 10,000 year time-scale? And, what is the finer-scale pattern of modern marine life found within and around the bioherms now that we understand their true shape?”
He said future research would require sediment coring, sub-surface geophysical surveys, and employing autonomous underwater vehicle technologies to unravel the physical, chemical and biological processes of the structures.
Link to paper:
New constraints on the spatial distribution and morphology of the Halimeda bioherms of the Great Barrier Reef, Australia:
High-res 3D images of the GBR bioherms can be seen at: http://ftt.jcu.edu.au/deepreef/temp/bioherms_image_caption.zip
*Laser Airborne Depth Sounder (LADS) uses red and green LiDAR technology to rapidly scan the seafloor to depths of about 50 metres, generating a dense grid of depth data points. The bathymetry data are then used by the Australian Hydrographic Service (AHS) to revise the nautical charts used by mariners.
* The Weapons Research Establishment first developed LADS airborne LiDAR bathymetry in Australia in 1972. The navy LADS Flight unit is based out of Cairns for year-round surveying of Australia’s shallow waters.
*Marine geologists previously understood the bioherms to form linear, dune-like parallel ridges and troughs, quite different to the complex seafloor now revealed with the benefit of LiDAR and multibeam swath bathymetry data collected in the past few years.
*Less than 15% of the Earth’s oceans deeper than about 200 metres have been mapped using modern surveying techniques.
Dr Robin Beaman (James Cook University, in Cairns)
Tel 07 4042 1693
Associate Professor Jody Webster (University of Sydney, in Sydney)
Tel 02 90366538
Ms Mardi McNeil (Queensland University of Technology, in Brisbane)
Tel 0438 690 879