Two new spaceborne Earth-observing instruments will help scientists better understand how global forests
Two new spaceborne Earth-observing instruments will help scientists better understand how global forests and ecosystems are affected by changes in climate and land use change. This image of the Amazon rainforest is from a 2010 global map of the height of the world's forests based on multiple satellite datasets. Image credit: NASA Earth Observatory
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NASA has selected proposals for two new instruments, including one from NASA's Jet Propulsion Laboratory, Pasadena, California, that will observe changes in global vegetation from the International Space Station. The sensors will give scientists new ways to see how forests and ecosystems are affected by changes in climate or in land use.

A high-resolution, multiple-wavelength imaging spectrometer from JPL will study the effectiveness of water use by vegetation. This instrument will be completed in 2018 and will not cost more than $30 million. A laser-based system from the University of Maryland, College Park, will observe the structure of forest canopy. This instrument will be completed in 2019 and will not cost more than $94 million.

"We are excited to expand the use of the International Space Station to make critical Earth observations that will help scientists understand the diversity of forests and vegetation and their response to a changing climate," said John Grunsfeld, associate administrator of NASA's Science Mission Directorate in Washington. "These innovative Earth Venture Instruments will join a growing suite of NASA Earth-observing sensors to be deployed to the station starting this year."

The instruments were competitively selected from 20 proposals submitted to NASA's Earth Venture Instrument program. Part of the Earth System Science Pathfinder program, Earth Venture investigations are small, targeted science investigations that complement NASA's larger research missions. The National Research Council recommended in 2007 that NASA undertake this type of regularly solicited, quick-turnaround project. The program's first selection was awarded in 2010.

Simon Hook of JPL is the principal investigator for the ECOsystem Spaceborne Thermal Radiometer Experiment on Space Station (ECOSTRESS). This project will use a high-resolution thermal infrared radiometer to measure plant evapotranspiration, the loss of water from growing leaves and evaporation from the soil. These data will reveal how ecosystems change with climate and provide a critical link between the water cycle and effectiveness of plant growth, both natural and agricultural.

The ECOSTRESS team has extensive experience in development and analysis of thermal infrared spectroscopic images of Earth's surface. Hook has served as project scientist for the Advanced Spaceborne Thermal Emission and Reflection Radiometer (ASTER) instrument on NASA's Earth Observing System Terra satellite and has been involved in numerous suborbital field campaigns. The team includes partnerships with the U.S. Department of Agriculture, Beltsville, Maryland, and Maricopa, Arizona; Princeton University, Princeton, New Jersey; and the University of Idaho, Moscow, Idaho.

Ralph Dubayah, of the University of Maryland, is the principal investigator for the Global Ecosystem Dynamics Investigation (GEDI) Lidar. This project will use a laser-based system to study a range of climates, including the observation of the forest canopy structure over the tropics, and the tundra in high northern latitudes. These data will help scientists better understand the changes in natural carbon storage within the carbon cycle from both human-influenced activities and natural climate variations.

The GEDI team has extensive experience in observing and modeling forest and vegetation dynamics. Dubayah has led numerous vegetation lidar observations from suborbital platforms throughout his career. The team includes partnerships with NASA's Goddard Space Flight Center, Greenbelt, Maryland; Woods Hole Research Center, Woods Hole, Massachusetts; the U.S. Forest Service, Ogden, Utah; and Brown University, Providence, Rhode Island.

The International Space Station provides several in-orbit capabilities useful to both instruments. The space station's orbit is inclined relative to the poles, providing more observation time of forests and vegetation over temperate land masses than possible from the polar orbits commonly used for other types of Earth observations. The GEDI laser requires significant power resources, which the space station can provide. Also, the relatively low altitude of the station's orbit, about 260 miles (418 kilometers) up, benefits GEDI by ensuring a higher return energy for laser pulses reflected from the ground.

In 2012, NASA selected the first Earth Venture Instrument investigation, the Tropospheric Emissions: Monitoring of Pollution (TEMPO) mission. TEMPO will be the first space-based sensor to monitor major air pollutants across North America hourly during daytime. It will share a ride on a commercial satellite as a hosted payload and orbit about 22,000 miles (35,400 kilometers) above the equator.

NASA's Langley Research Center in Hampton, Virginia, manages the Earth System Science Pathfinder program for NASA's Science Mission Directorate. The missions in this program provide an innovative approach to address Earth science research with periodic windows of opportunity to accommodate new scientific priorities. For more information, visit:

http://go.nasa.gov/MKvgJO


Media Contact

Alan Buis
Jet Propulsion Laboratory, Pasadena, California
818-354-0474
alan.buis@jpl.nasa.gov

Steve Cole
NASA Headquarters, Washington
202-358-0918
stephen.e.cole@nasa.gov

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