Mutant soybeans planted as part of a campaign to support the development of ESA’s FLEX mission can be seen clearly as the bright blue strip in the centre of the image. The image was captured by the airborne HyPlant, which comprises two ‘imaging spectrometers’ – essentially cameras that see the reflected and the emitted light from the surface at different wavelengths. The mutant soybean plants only have 20% of the chlorophyll of ‘normal’ green plants. Such chlorophyll deficiency changes the properties of the leaves, which are a yellowy colour. As such, these mutant soybean leaves reflect much more sunlight than their green cousins, leaving the plant with less energy to photosynthesise. Although they have less energy, these mutants are surprisingly more efficient at fixing carbon dioxide from the air. Traditional satellite techniques rely on measuring aspects of reflected light to estimate plant productivity and cannot account for unusual coloured plants. ESA’s FLEX mission, however, will use a novel technique to map plant health. It will detect and measure the faint glow that plants give off as they photosynthesise, so non-green plants will be measured like normal green plants. Credit: FZ-Juelich Because a plant isn’t green doesn’t mean it can’t photosynthesise as well as its more usual counterpart, but when measured by satellites, these non-green varieties skew results on plant health. FLEX is different. Experiments using ’mutants’ show that colour won’t be an obstacle in this new mission’s task of mapping plant health from space. Planned for launch around 2022, ESA’s Fluorescence Explorer – FLEX – will use a novel technique to track the health of the world’s vegetation.
This technique involves detecting and measuring the faint glow that plants give off as they use sunlight to convert carbon dioxide into energy-rich carbohydrates – photosynthesis.
FLEX will improve our understanding of the way carbon moves between plants and the atmosphere and how photosynthesis affects the carbon and water cycles.
Moreover, accurate information about the health and stress of the planet’s vegetation is important as the growing global population places increasing demands on the production of food and animal feed.
As part of the development of this new satellite mission, scientists in Italy and Germany have been studying different crops to understand the relationship between the light reflected by different plants and their carbon uptake.
The latest field campaigns focus on the natural mutant soybean MinnGold, which only has 20% of the chlorophyll of ’normal’ green plants. As part of an airborne campaign to support the development of ESA’s FLEX mission, a field was planted with normal soybeans (left ) and MinnGold natural mutant soybeans (right). Credit: ESA–D. Schuettemeyer Such chlorophyll deficiency changes the properties of the leaves, which are a yellowy colour. As such, these mutant soybean leaves reflect much more sunlight than their green cousins, leaving the plant with less energy to photosynthesise.
Although they have less energy, these mutants are surprisingly more efficient at fixing carbon dioxide from the air.
Traditional satellite techniques rely on measuring aspects of reflected light to estimate plant productivity and cannot account for unusual coloured plants.
Radoslaw Juszczak from the Poznań University of Life Sciences in Poland explained, ”Chlorophyll-deficient plants having similar photosynthetic rates as their green counterparts.
”But, indeed, they pose a challenge for conventional reflectance-based remote sensing methods to estimate photosynthesis.”
Since FLEX takes a different approach by measuring the florescence that plants give off as they photosynthesise, plant colour will no longer be an obstacle. The Fluorescence Explorer (FLEX) mission is ESA’s eighth Earth Explorer. FLEX will provide global maps of vegetation fluorescence, which can be converted into an indicator of photosynthetic activity. This new information will improve our understanding of how much carbon is stored in plants and their role in the carbon and water cycles. FLEX was selected in November 2015 and is expected to be launched by 2022. Credit: ESA/ATG medialab Nevertheless, field experiments are needed to confirm that this is the case.
The latest campaign uses the HyPlant sensor – an airborne demonstrator developed for FLEX by FZ-Juelich in Germany. It comprises two ’imaging spectrometers’, which are essentially cameras that see the reflected and the emitted light from the surface at different wavelengths.
Dirk Schuettemeyer, ESA’s campaign coordinator, said, ”For the first time, we can test these new ideas related to plant physiology that can be detected by airborne instruments, paving the way for the FLEX instrument under development.
”In the first instance, HyPlant can clearly see the long strip of soybean mutants next to the green fields. The next step is to quantify fluorescence for the different fields to prove the theory of similar photosynthetic rates for mutant and original soybean crops.”
The campaign teams are now busy processing and analysing the data collected. The first results will be presented at a workshop in January.
Explore further:Glowing plants a sign of health
Provided by:European Space Agency