Moore, a postdoctoral fellow at the Harvard-Smithsonian Center for Astrophysics in the Solar and Stellar X-ray Group, will describe how the twin Miniature X-ray Solar Spectometer (MinXSS) CubeSats measure soft X-rays from the Sun.
These were the first solar science-oriented CubeSat missions flown for the NASA Science Mission Directorate. As he will describe at the meeting, Moore was one of several dozen graduate students who contributed to MinXSS over its lifetime. He worked on the MinXSS CubeSats as part of his doctoral research at the University of Colorado Boulder. "This work demonstrated that these small, relatively cheap -- ranging from $1 million to $2 million for MinXSS -- CubeSats can collect data that fills a specific niche and is consistent with large satellites, which are much more expensive, and contribute to major science investigations," said Moore. MinXSS-1 was launched in December 2015 on the Atlas-V Cygnus OA-4 Launch, Orbital ATK resupply mission to the International Space Station, where it was deployed for an approximately 12-month orbit around Earth.
The second version, MinXXS-2, was launched on the SpaceX Falcon 9 as part of the Spaceflight SSO-A: SmallSat Express in December 2018 and deployed for a four- to five-year orbit and operation. Science-oriented CubeSats are low-cost, short-lifespan satellites built to take specific scientific observations and measurements. MinXSS, for example, features cost-saving components such as an extendable tape measure that serves as a radio antenna. Its science payload consists of a soft X-ray spectrometer that was modified for compatibility with the harsh environment of space. MinXSS is also carrying silicon-based photometers onboard for other soft X-ray and visible light measurements.
The NASA-funded MinXSS-1 (the first of the twin satellites) was the initial test of the Blue Canyon Technologies XACT, which is a miniaturized attitude determination and control system.
The success of MinXSS-1 and XACT resulted in the SmallSat 2016 Mission of the Year award. "MinXSS measures solar soft X-rays between 0.5 to 12 kiloelectron volts at moderate spectral resolution, which includes the sparsely observed 0.5- to 2-keV bandpass," explained Moore. "This spectral region is highly informative of the solar atmospheric plasma conditions for temperatures greater than 2 million kelvin present in solar flares and during quiescence (dormancy)." The data collected by MinXSS has been consistent with inferences from large satellites. "MinXSS data will help us understand the physics behind solar flares," Moore said. "The soft X-rays carry information about the temperature, density and chemical composition of material in the Sun's atmosphere, which allows scientists to trace how events like flares and other processes during calmer times heat the surrounding material in the corona, the Sun's atmosphere." Variations of the solar X-ray emission strongly correlate with large-scale magnetic features called active regions. "These active regions appear as bright loops in soft X-rays, but appear as dark spots at the solar surface (the photosphere), so they're called 'sunspots.' MinXSS data can help directly constrain the plasma temperature of these relatively quasi-static features," Moore said. CubeSats provide "excellent opportunities to train future leaders in technology and science, as undergraduate students, graduate students and postdocs commonly have pivotal roles in design, development, testing, mission operations and science analysis," said Moore. "More than 40 graduate students at the University of Colorado Boulder contributed to MinXSS over the project's lifetime." Due to recent CubeSat successes, NASA and the National Science Foundation now offer new funding opportunities to directly fund science-oriented.
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