An experimental small satellite has successfully collected and delivered data on a key measurement for predicting changes in Earth’s climate.
An experimental small satellite has successfully collected and delivered data on a key measurement for predicting changes in Earth’s climate.
The Radiometer Assessment using Vertically Aligned Nanotubes (RAVAN) CubeSat was launched into low-Earth orbit on Nov. 11, 2016, in order to test new technologies that help to measure Earth’s radiation imbalance, which is the difference between the amount of energy from the Sun that reaches Earth and the amount that is reflected and emitted back into space. That difference, estimated to be less than one percent, is responsible for global warming and climate change.
Designed to measure the amount of reflected solar and thermal energy that is emitted into space, RAVAN employs two technologies that have never before been used on an orbiting spacecraft: carbon nanotubes that absorb outbound radiation and a gallium phase change blackbody for calibration.
Among the blackest known materials, carbon nanotubes absorb virtually all energy across the electromagnetic spectrum. Their absorptive property makes them well suited for accurately measuring the amount of energy reflected and emitted from Earth. Gallium is a metal that melts — or changes phase — at around body temperature, making it a consistent reference point. RAVAN’s radiometers measure the amount of energy absorbed by the carbon nanotubes, and the gallium phase change cells monitor the stability of the radiometers.
Read more at NASA/Goddard Space Flight Center
Image: A fully implemented RAVAN mission entails a constellation of multiple RAVAN satellites distributed around the planet to measure Earth's outgoing energy globally. (Credit: Johns Hopkins University Applied Physics Laboratory/Blue Canyon Technologies)