ARC Centre of Excellence for Coral Reef Studies
James Cook University Townsville
Queensland 4811 Australia
Phone: 61 7 4781 4000
Email: info@coralcoe.org.au
Big waves are energetically costly for fish, and there are more big waves than ever. The good news is that fish might be able to adapt.
“There has been a lot of recent work in oceanography documenting the fact that waves are becoming more frequent and more intense due to climate change,” says Mr Dominique Roche, PhD candidate from the Research School of Biology. “The habitats that fish live in are changing.”
“This is not a localised problem, but something that is documented globally,” adds Ms Sandra Binning, also a PhD candidate in the Research School of Biology.
Mr Roche and Ms Binning are co-authors on a study documenting the energy it takes for fish to swim through large, intense waves. Specifically, they focused on fish that swim with their arm, or pectoral fins, which are very common on both rocky and coral reefs.
“By controlling water flow in an experimental chamber with the help of a computer, we were able to replicate oscillations in the water flow like in a wave pool,” explains Mr Roche.
“We looked at how much energy the fish consumed while swimming without waves, in conditions with small waves, and in conditions with large waves. The idea was to compare the amount of energy that fish consume while swimming in these three conditions when their average swimming speed was exactly the same.”
Mr Roche and Ms Binning found that it’s a lot more energetically demanding for fish to deal with large fluctuations in water speed and wave height.
“It’s harder to constantly switch speeds than it is to remain at a constant speed, like a runner changing between running and a walking during interval training versus a steady jog. Well, it’s the same for swimming fish,” says Mr Roche.
“Things could get tough for fish in windy, exposed habitats if waves get stronger with changing climate. But there may be a silver lining,” says Ms Binning.
“In the swim chamber, when the water flow increased, fish had to beat their fins faster to keep up. But when the water flow slowed down, some fish took advantage and rode the wave. Essentially, rather than beating their fins frantically, these fish used the momentum that they had gained while speeding up to glide and save energy.
“This means that some individuals are better at dealing with waves than others, and that there is hope for populations to adapt their swimming behavior to potentially changing conditions in the future,” concludes Mr Roche.
Their research was recently published in the Journal of Experimental Biology. A copy, plus images and video, can be obtained from the ANU Media Office.
For further information contact:
Mr Dominque Roche, PhD Candidate, ARC Centre of Excellence for Coral Reef Studies and ANU, +1-514-482-1805, dominique.roche@anu.edu.au, Skype: dominique.roche
Ms Sandra Binning, PhD Candidate, ARC Centre of Excellence for Coral Reef Studies and ANU, +1-514-291-6005, sandra.binning@anu.edu.au
Please note that Roche and Binning are currently in Montreal, Canada. The time difference is -16hrs.
For media assistance, please call the ANU media hotline: (02) 6125 7979
The most extensive reef survey of the Coral Sea Marine Park ever undertaken will continue this week as scientists from ARC Centre of Excellence for Coral Reef Studies at James Cook University (Coral C
Scientists have used modern genetic techniques to prove age-old assumptions about what sizes of fish to leave in the sea to preserve the future of local fisheries. “We’ve known for decades that
Scientists say outdated assumptions around gender continue to hinder effective and fair policymaking and action for climate mitigation and adaptation. Lead author of a new study, Dr Jacqueline Lau
For the first time, scientists have assessed how many corals there are in the Pacific Ocean—and evaluated their risk of extinction. While the answer to “how many coral species are there?” is
Abstract: The fate of fish larvae during the pelagic phase has profound effects on replenishment of marine populations that are critical for human and ecosystem health. The survival and transport of l
Abstract: Neonate sharks experience high predation during early ontogeny. For this reason, predator avoidance is the major driver of shallow-water habitat use in neonate sharks. When a predator encoun
Abstract: Humans have been harvesting predators and other creatures from the global oceans for millennia. More recently, conservation measures, such as marine reserves, have been established to restor
Abstract: The Great Barrier Reef World Heritage Area (WHA) is one of the most precious and diverse ecosystems on Earth. It is highly valued by people within Australia and worldwide and is critical to
Abstract: We frequently hear about demise and decline in fisheries systems. This narrative can inadvertently shift thefocus of research and funding away from the opportunities and benefits avail
Abstract: Multiple habitats in a tropical seascape are increasingly recognized as interconnected to one another. Mangroves, seagrass beds, and macroaglal beds are important components of a tropical se
Abstract: Current conservation goals for reef-building corals under climate change involve boosting desirable traits like heat tolerance and fast growth in natural and restored coral populations. This
Abstract: Coral reefs are threatened by local and global stressors, and critical to managing corals for persistence is understanding the components of how coral populations resist and recover from st
Partner Research Institutions
ARC Centre of Excellence for Coral Reef Studies
James Cook University Townsville
Queensland 4811 Australia
Phone: 61 7 4781 4000
Email: info@coralcoe.org.au
