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New technique tracks plant photosynthesis from space

13 October 2017

University of Sydney and NASA researchers have developed a revolutionary new technique to image plant photosynthesis using satellite-based remote-sensing, with potential applications in climate change monitoring.

Image showing visualisation of estimated changes of inter-annual GPP in Australia and the pacific

Visualisation of estimated changes of inter-annual GPP in Australia and the Pacific. Credit: Dr Bradley Evans.

The uptake of carbon dioxide by leaves and it’s conversion to sugars by photosynthesis, referred to as gross primary production (GPP), is the fundamental basis of life on Earth and its quantification is vital for research on terrestrial carbon cycle dynamics.

This new study, published in the journal Science, uses satellite-based monitoring to measure solar-induced chlorophyll fluorescence – a by-product of photosynthesis in leaves. Crucially, the study also shows how these fluorescence measurements correlate with GPP observations on the ground from diverse locations, areas of vegetation, and over various timeframes.

This observed link between fluorescence and plant carbon dioxide uptake opens up many potential applications of this technique, such as for climate change and ecosystem monitoring, biodiversity conservation, and land management.  

Dr Bradley Evans, co-author of the study and Senior Lecturer at the School of Life and Environmental Sciences, has been collaborating with NASA's David Schimel and his team to develop a more direct way of measuring plant growth using the Orbiting Carbon Observatory-2 (OCO2) satellite.

Dr Evans said: “The OCO2 satellite created such an amazing opportunity, and particularly when we discovered a significant relationship between the fluorescence of plants and the satellite imagery.

"We’re really excited by our results, and how they are a step closer to a quantitative estimate of the photons of light resulting from photosynthesis. We also hope that our results will help others to better quantify carbon flows, so that we can understand more about Earth’s climate and ecosystem.”

This work is a very impressive accomplishment, and publication in one of the world’s most prestigious journals shows the importance of these results.
Sydney Informatics Hub director, Professor Dietmar Müller

Dr Evans’s research was enabled by the Sydney Informatics Hub, the University’s Core Research Facility dedicated to advancing high-performance computing, data science and open-access research data management capabilities.

Hub director Dietmar Müller said: “This work is a very impressive accomplishment, and publication in one of the world’s most prestigious journals shows the importance of these results.

“It’s great to see how Sydney's commitment to building a world-class informatics capability is already starting to enable our researchers to achieve truly great things.”

Visualisation of the vegetation functional gradients across a transect of temperate deciduous forests, croplands, and urban area with solar-induced chlorophyll fluorescence (SIF).

Visualisation of the vegetation functional gradients across a transect of temperate deciduous forests, croplands, and urban area with solar-induced chlorophyll fluorescence (SIF). Reproduced from Sun et al., Science 358, eaam5747 (2017)

 

This publication continues the recent success of these researchers and their work with the Hub, having also just published a related article in Nature Plants about the development of a universal model for terrestrial carbon and water cycling.

Vivienne Reiner

PhD Candidate and Casual Academic
Address
  • Integrated Sustainability Analysis,

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