Mapping the energy of lightning in space
Beyond CANVAS
CANVAS is just one of three different CubeSats projects Marshall is developing. His team is also working on development of the COSMO and AEPEX nano-satellites:
COSMO
COSMO, the Compact Spaceborne Magnetic Observatory, aims to reduce the cost of mapping Earth’s magnetic field. The technology particularly has applications to navigation, which is impacted by magnetic anomalies below Earth’s surface. Development began in 2018.
AEPEX
AEPEX, the Atmospheric Effects of Precipitation through Energetic X-rays mission, is a CubeSat project for which Marshall is preparing a concept study for NASA. If it is selected for full funding, the satellite will investigate electrons that fall into Earth’s atmosphere from the Van Allen radiation belts. The electrons interact with the atmosphere and have major implications for the atmospheric ozone balance.
A lightning strike releases an incredible amount of energy, most of it felt on Earth’s surface, but some of that energy travels up, far above the clouds and into space, and a new satellite is being designed by the ˛ĘĂń±¦µä to map the phenomenon.
While there is no chance of an orbiting satellite being hit by errant bolts from a thunderstorm, the energy from lightning influences the ionosphere, an area of the atmosphere between 80-600 kilometers (50-375 miles) above Earth’s surface, and the magnetosphere above that, extending to 30,000 miles above the Earth’s surface.
“We’ve discovered over the past few decades that a lot of energy from Earth is injected into space by ground-based sources, including lightning and certain very low frequency (VLF) radio transmitters,” said Bob Marshall, an assistant professor in the Ann and H.J. Smead Department of Aerospace Engineering Sciences. “We want to map that energetic wave activity, to get a global picture of when and where these waves exist.”
Marshall has received a four-year, to develop the satellite. This research could previously only have been done by much larger and far more costly ($50 million or more) satellites. Advancing technology has made it possible for a radically less expensive solution.
Meet CANVAS (Climatology of Anthropogenic and Natural VLF wave Activity in Space), a nanosatellite, or CubeSat, roughly the size of a loaf of bread, being tasked with the mission. Once launched, it will map these waves to determine their magnetic field intensity, electric field intensity, power level, and direction of propagation through a region of the ionosphere.
As Marshall’s team develops the satellite, they are facing some unique obstacles. Chief among them is the fact that the instrument used to collect this type of data is so sensitive the satellite’s own electronics can cause interference.
“The search coil has to be deployed a decent distance from the satellite. So we’re using a one meter carbon fiber boom that rolls up inside the satellite for launch and is deployed once it reaches orbit,” Marshall says.
Once the data is collected, they are facing a second problem: transmitting everything to Earth. The instrument will take in up to 60 gigabytes of information every day, but the team can only communicate with the satellite during brief windows when it passes over Boulder.
“We could only download far less than one percent of what it would store. So we have to process the signals it records on the satellite to reduce the data volume,” Marshall said.
CANVAS will incorporate a five-channel Field Programmable Gate Array (FPGA) to do the work. The FPGA expands on an earlier design Marshall previously worked on for the VPM CubeSat, an Air Force Research Laboratory project expected to launch later this year.
While not part of the CANVAS mission, the wave maps it generates could eventually be used to help predict changes in Earth’s Van Allen radiation belts, an area of dynamic populations of charged particles that encircle our planet. The radiation in the Van Allen belts can be harmful to astronauts and orbiting satellites.
CANVAS is tentatively set for launch in 2022.