SwRI-Designed Miniature Spacecraft Selected To Fly On Orion/SLS Test Flight

Southwest Research Institute is leading the development of the CubeSat to study Solar Particles (CuSP), a microsatellite to study interplanetary magnetic fields and energetic particles in the solar wind.  Image Credit: SwRI

Southwest Research Institute is leading the development of the CubeSat to study Solar Particles (CuSP), a microsatellite to study interplanetary magnetic fields and energetic particles in the solar wind. Image Credit: SwRI

February 3, 2016 – NASA announced that a miniature solar particle research spacecraft to be built by Southwest Research Institute (SwRI) will launch aboard NASA’s Exploration Mission 1 (EM-1) rocket in 2018.

The CubeSat to study Solar Particles (CuSP) is one of a dozen shoebox-size payloads, called CubeSats, that will hitchhike into interplanetary space aboard EM-1, the first uncrewed test flight of NASA’s new Space Launch System (SLS). The SLS rocket is designed to eventually carry astronauts to the Moon and Mars aboard the Orion spacecraft.

Once the CubeSat is ejected, it will orbit around the sun in interplanetary space, measuring incoming radiation that can create a wide variety of effects at Earth, from interfering with radio communications to tripping up satellite electronics to creating electric currents in power grids.

CuSP will reside in interplanetary space, where it can observe particles and magnetic fields from the sun on their way toward Earth — where they can create a wide variety of space weather effects from interfering with radio communications to tripping up satellite electronics to creating electric currents in power grids. Here a (not-to-scale) CubeSat is shown within an artist’s rendition of the constantly moving magnetic fields around Earth. Image Credit: NASA’s Goddard Space Flight Center

“CuSP will be able to observe events in space hours before they reach Earth,” said Mihir Desai, the principal investigator for CuSP at the Southwest Research Institute. “Such interplanetary observations would give us significant insight into what drives space weather, helping scientists to improve their simulations.”

CuSP is a six-unit CubeSat, meaning it has a total volume of about six liters. This micro-satellite will carry three instruments, and the observations from those instruments will give us an unprecedented look at our interplanetary space environment, which is driven by the sun. The sun releases a constantly-flowing stream of particles and magnetic fields, known as the solar wind. Interspersed are faster, denser clouds of solar wind material, known as coronal mass ejections, or CMEs. When these CMEs – or even a particularly fast stream of solar wind – reach Earth, they can interact with Earth’s magnetic field, creating what’s called a geomagnetic storm. It is the buffeting of the magnetic fields and the release of energy that can stress power grids and impact space technology. To understand these effects on Earth, scientists want to track how the space environment changes and develops between the sun and Earth.

Currently, measurements of the space environment come from a dozen or so satellites, all carrying different sets of instruments. Most of these satellites are in one of two basic orbits – circling either Earth or the L1 Lagrange point, a point between Earth and the sun about a million miles from us.

“Right now, it’s like we’re trying to understand weather for the entire Pacific Ocean with just a handful of weather stations,” said Eric Christian, lead Goddard scientist for CuSP. “We need to collect data from more locations.”

To create a network of space weather stations would require many instruments scattered throughout space millions of miles apart. But the cost of putting together such a system built out of full-fledged satellite missions is prohibitive. CubeSats like CuSP might be able to help solve the problem. Though the satellites can only carry a few instruments apiece, they’re relatively inexpensive to launch because of their small mass and standardized design. So, CuSP also serves as a test for creating a network of space science stations.

“If you had, say, 20 CubeSats in different orbits, you could really start to understand the space environment in three dimensions,” said Christian.

The three instruments that CuSP carries will each provide a different contribution. The Suprathermal Ion Spectrograph, or SIS, is built by the Southwest Research Institute to detect and characterize low-energy solar energetic particles. NASA Goddard’s Miniaturized Electron and Proton Telescope, or MERiT, will return counts of high-energy solar energetic particles. Finally, the Vector Helium Magnetometer, or VHM, being built by NASA’s Jet Propulsion Laboratory, will measure the strength and direction of magnetic fields.

Originally known as CuSPP, for CubeSat to study Solar Particles over the Poles, the satellite was designed to fly in low-Earth orbit, studying solar particles near Earth’s poles. When NASA announced plans to fly CubeSats on SLS test flights, the team realized they had an opportunity to conduct interplanetary space weather research for a fraction of the usual cost. With a small amount of additional funding by NASA’s Heliophysics Technology and Instrument Development for Science program, the team is reconfiguring CuSP for interplanetary operations.