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NASA Collaboration Using Harvard Technology Could Advance Earth Science from Orbit

Metasurface technology uses nano-scale physics to reveal light's polarization.

Sunlight traveling through the atmosphere becomes polarized in different ways as it is scattered by water vapor, ice, aerosols created by living organisms, dust, and other particulates.

Measuring that polarization lets scientists extrapolate what is in the atmosphere, and the next generation of polarimeters for the job could benefit from a new technology developed by researchers at Harvard University, Cambridge, Massachusetts.

Earth scientist Kerry Meyer at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, is working with Harvard partners to develop a science use for their “metasurface” technology. Using one flat optical component, the technology can analyze light along four polarization directions, allowing for a full characterization of light’s polarized state: intensity, linear polarization (horizontal and vertical), and circular polarization.

“Up until recently, polarimeters have been pretty large instruments, and depending on the measurement strategy, could involve lots of moving parts and different optics,” said Meyer. “This metasurface technology splits the incoming signal into all four states.”

white pillars on a gray field - microscope image
Kerry Meyer with NASA’s Goddard Space Flight Center in Greenbelt, Maryland, is working with a new metasurface material developed by Harvard researchers to develop new lightweight polarimeters.u003cbru003e
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Without the moving parts, this technology could enable polarimetry in small satellites like SmallSats and CubeSats but could also be scaled up for use on larger missions at a significant cost, volume, weight and power savings over existing technology.

While the Harvard technology is still in early development, Goddard scientist Dan Miller said a type of polarimeter is expected to fly as part of the NASA’s planned Earth System Observatory on the Aerosol, Cloud, Convection and Precipitation (ACCP) mission recommended in the 2017 Earth Decadal Survey.

Expected to go into development this year, this mission would, among other things, combine polarimetry with lidar data to provide new insights into the clouds and particles in the atmosphere and how they affect life on Earth. Lidar means Light Detection and Ranging and it is a remote sensing method that uses light in the form of a pulsed laser to measure variable distances to the Earth.

“The combination of a lidar and a polarimeter in orbit, observing the same target, tells you both what you’re looking at and the vertical distribution — where it is in the atmosphere,” Miller said.

The partnership gave Harvard postdoctoral researcher Noah Rubin valued insight into the science use cases for his technology.

“Working with our new colleagues at NASA has been great,” Rubin said. “My team at Harvard were primarily concerned with new physics and optical technologies enabled by controlling light at the nanoscale. It’s rare, however, that we get the chance to interact with potential end-users in such a direct way, not to mention at such an early stage in a new technology’s development.”

For Earth scientist Ed Nowottnick, the Harvard technology makes distributed observations of clouds and aerosolized particles one step closer to reality.

“I could see flying this sensor in space as a constellation,” he said. “If you could put up multiple copies, you can improve your coverage over time. Then, you’re really going a long way toward understanding atmospheric processes.”

Payouts would include better forecasting of weather, aerosol particles, and clouds, as well as a stronger understanding of how climate change could affect these processes in the future.

By Karl Hille

NASA’s Goddard Space Flight Center in Greenbelt, Md.