Explaining the history of Australia's vegetation

Thursday, 17 May 2018

Australia's vegetation

University of Adelaide-led research has uncovered the history of when and why the native vegetation that today dominates much of Australia first expanded across the continent.

The new understanding will help researchers better predict the likely impact of climate change and rising CO2 levels on these critically important plants. Called ‘C4 plants’ after their alternative photosynthetic pathway, these plants include a wide variety of native tropical, subtropical and arid grasses as well as saltbushes. C4 crops include sugarcane and corn.

“C4 plants evolved to be able to photosynthesise under warm, dry, and low CO2 conditions, with a special ability to take advantage of summer rainfall,” says lead author Jake Andrae, PhD candidate in the University’s School of Physical Sciences and Sprigg Geobiology Centre. “As a result, they dominate the vegetation of Australian tropical, subtropical, and arid regions today.

“But despite being the most C4-dominated continent today, little is known about the initial C4 expansion in Australia.”

The researchers analysed fossilised leaf waxes and pollen preserved in marine sediments. They measured the chemical signatures from these remnants, to reconstruct how and when C4-dominated ecosystems first rose to prominence in Australia.

“In many regions around the globe, C4 plants became prevalent between six and eight million years ago, which is thought by some to be the result of falling global atmospheric CO2 concentrations during this time,” says project leader Dr Francesca McInerney, Australian Research Council Future Fellow at the University of Adelaide.

“Surprisingly, in north-west Australia C4 plants did not expand at this time in spite of regionally arid conditions and falling atmospheric CO2, both of which should have promoted C4 vegetation. Instead, C4 vegetation expanded across the landscape only 3.5 million years ago, several million years later.”

The authors say that the rise of C4 plants in Australia was likely the result of a strong summer monsoon that developed around that time.

“The difference in the timing of the expansion of C4 plants in Australia from other parts of the globe demonstrates that regional climate changes are important in driving vegetation change,” Dr McInerney says.

“In the future, the interaction between global atmospheric CO2 and regional changes in seasonality of rainfall is likely to play an important role in the distribution of C4-dominated ecosystems. Rising CO2 will place C4 plants at a disadvantage, while rising temperatures, and changes in the season and amount of rainfall, could favour them.

“In Australia, C4 plants are critical to grazing, soil carbon storage and biodiversity. We need to understand the factors that are likely to influence their survival in the future, to provide a basis for future conservation of these important plants.”

The research, in collaboration with Columbia University and University of Melbourne, has been published online in Geophysical Research Letters.


Image:
C4-dominated Australian landscape: Triodia pungens dominated hummock grassland with scattered Acacia and Eucalyptus, on Mittebah Station in the Northern Territory. Photograph courtesy of Terrestrial Ecosystem Research Network (TERN)


 

Contact Details

Dr Francesca McInerney
Email: cesca.mcinerney@adelaide.edu.au
ARC Future Fellow
School of Physical Sciences
The University of Adelaide
Business: +61 (0) 8 8313 0228
Mobile: +61 (0)427 032 681


Mr Jake Andrae
Email: jake.andrae@adelaide.edu.au
PhD candidate
School of Physical Sciences
The University of Adelaide
Mobile: +61 (0) 407 701 565


Media Team
Email: media@adelaide.edu.au
Website: https://www.adelaide.edu.au/newsroom/
The University of Adelaide
Business: +61 8 8313 0814