NASA INDEX
USES PLANTS TO
SHED NEW LIGHT ON DROUGHTS
NASA has a new tool designed to keep a close watch over our plants. What
we see in the reflection of the vegetation may help researchers do a better
job of monitoring and, one day, predicting periods of drought.
A new Multi-spectral Drought Index measures the impacts of too little water
or too much rainfall on vegetation. The index will also be used to verify
other existing drought-monitoring products.
"What makes this data set unique is its unprecedented detail, which provides
a resolution four times that of current drought prediction maps, and it is
based on a 20-year data record," said Compton Tucker, the research scientist
leading the project at NASA's Goddard Space Flight Center, Greenbelt, MD.
The new Multi-spectral Drought Index utilizes and improves the data from the
Normalized Difference Vegetation Index (NDVI) and shows deviations from
average vegetation levels. The NDVI is an index created by Tucker 20 years
ago to measure the absorption and reflectance of sunlight by plants.
The NDVI data sets show the greening and browning of plants as they relate
to seasonal changes and conditions such as drought or abundant rainfall. The
data is gathered by the polar-orbiting satellites built by NASA and operated
by the National Oceanic and Atmospheric Administration.
The satellites measure the reflectance and absorption characteristics of
plants at different wavelengths in the electromagnetic spectrum. The data
are registered in numerical form, and translated by researchers into monthly
maps of vegetation color changes, which in turn indicate how much soil
moisture is available to plants. Since the global data set spans a 20-year
time period, researchers can better determine what are "normal" levels of
plant growth, and what are unusually high or low levels.
Sunlight can either be absorbed by leaves and needles or scattered within
and among them. By using red and infrared wavelengths in the spectrum,
multi-spectral imaging measures the absorption rate of sunlight and
identifies levels of chlorophyll generated in vegetation. When more sunlight
is absorbed, higher levels of chlorophyll are generated in vegetation
showing plant growth. Conversely, when a plant is stressed from lack of
fertilizer or water, it will limit its chlorophyll production compared to
healthy plants.
"The new Multi-spectral Drought Index is used to generate better vegetation
anomaly maps than before," according to Tucker. Light brown on the drought
map means there's diminished plant growth, green on the map indicates a
indicates that."
Many drought products are based on water availability in soils. The new
index maps integrate climate variables such as soil moisture, temperature
and precipitation, and show how vegetation responds to environmental
conditions around the world.
"The bottom line is that the new Multi-spectral Drought Index reflects the
actual environmental conditions of the vegetation, and at a much higher
resolution than previously available, which will be helpful in supplementing
and validating the NOAA drought forecast maps," Tucker said.
The first data sets covering North America and Africa and are currently
available at:
Earth Observatory
Images and animations are available at
https://svs.gsfc.nasa.gov/stories/drought/index.html
Complete data sets including images from all continents are expected to
be released to the scientific community early next year. This research is
done in support of NASA's Earth Science Enterprise, Washington DC. The Enterprise
is dedicated to the long-term study of how human-induced and natural changes
affect our global environment. More information about the Enterprise can
be found at:
https://science.nasa.gov/earth-science/
Special Thanks to
Dr. Compton Tucker
Please give credit for these images to:
NASA - Goddard Space Flight Center
NOAA
Scientific Visualization Studio
Television Production NASA-TV/GSFC
Content Preparation & Project Production:
Michael Starobin
Last Revised: May 26, 2003 at 02:05 PM EDT