Field experiments have shown how ESA’s potential FLEX mission could identify vegetation that is suffering degrees of stress invisible to the naked eye.
The Fluorescence Explorer, or FLEX for short, is one of the two missions vying to be selected as ESA’s eighth Earth Explorer. It aims to provide global maps of vegetation fluorescence that can reflect photosynthetic activity and plant health and stress.
In turn, this is not only important for a better understanding of the global carbon cycle, but also for agricultural management and food security.
Although most people have heard of the process that describes how plants convert energy in sunlight into organic compounds, photosynthesis involves an extremely complex chain of events.
In fact, it is so involved that no fewer than 10 Nobel prizes have been awarded for efforts unravelling the secret that is so fundamental to sustaining life on Earth.
From space, FLEX proposes to measure fluorescence as an indicator of photosynthetic activity.
Working in sequence, there are two different ‘solar power systems’ inside plant and algae cells. They collect energy in sunlight and produce subject to environmental conditions and the health of the plant chemical energy for photosynthesis, heat, and a faint glow called fluorescence.
Depending how efficiently the plant works, both solar power systems glow with different intensities at different wavelengths.
As part of the development of the FLEX mission concept, scientists have been carrying out field campaigns to study the efficiency of these two systems by using the Hyplant instrument on an aircraft to measure fluorescence emitted from vegetation.
Hyplant has two ‘imaging spectrometers’ essentially cameras that see at different wavelengths. One covers from red to near-infrared and splits up the wavelengths finely to pick out the fluorescence signals.
One of the key aspects of these campaigns involved using remote sensing to detect photosynthetic activity when it is under stress.
This was done by rolling out two fields of turf and applying one with a common herbicide blocking the energy transported between the two power systems and leaving the other untreated.
Fluorescence measured a few hours after the herbicide had been applied was significantly higher in the treated field than in the untreated field.
This is explained by the fact that the energy collected in the two power systems cannot be used for photosynthesis when the energy transport chain is interrupted.
To get rid of the absorbed solar energy the two power systems emit more radiation, with the glow much stronger than under unstressed conditions.
So, in short, detecting these initial abnormal peaks in fluorescence offers an early warning of stress in plants that may appear healthy to the eye.
Fluorescence measured a few hours after the herbicide had been applied was significantly higher in the treated field than in the untreated field.
This is explained by the fact that the energy collected in the two power systems cannot be used for photosynthesis when the energy transport chain is interrupted.
To get rid of the absorbed solar energy the two power systems emit more radiation, with the glow much stronger than under unstressed conditions.
So, in short, detecting these initial abnormal peaks in fluorescence offers an early warning of stress in plants that may appear healthy to the eye.