Today, NASA’s (MAVEN) spacecraft celebrates four years in orbit studying the upper atmosphere of the Red Planet and how it interacts with the sun and the solar wind. To mark the occasion, the MAVEN team has released a selfie image of the spacecraft at Mars.
“MAVEN has been a tremendous success,” said Bruce Jakosky, principal investigator on the MAVEN mission and a professor at CU Boulder’s (LASP). “The spacecraft and instruments continue to operate as planned, and we’re looking forward to further exploration of the Martian upper atmosphere and its influence on climate.”
MAVEN’s selfie was made by looking at ultraviolet wavelengths of sunlight reflected off of components of the spacecraft. The image was obtained with the Imaging Ultraviolet Spectrograph (IUVS) instrument, which was built at LASP and normally looks at ultraviolet emissions from the Martian upper atmosphere.
The IUVS instrument is mounted on a platform at the end of a 1.2-meter boom (its own “selfie stick”), and by rotating, the boom can look back at the spacecraft. The selfie was made from 21 different images, obtained with the IUVS in different orientations, that have been stitched together.
“We never expected MAVEN to be able to take its own picture this way, but MAVEN has already surprised us many times with its outstanding performance at Mars,” said Nick Schneider, a professor in LASP and lead scientist for the IUVS instrument. “We think this is the first ultraviolet selfie taken by a spacecraft."
The MAVEN team in LASP includes researchers and students at both the graduate and undergraduate level. MAVEN has been streaming data back to Earth since the spacecraft went into orbit around Mars on Sept. 14, 2014. LASP provided two instruments for MAVEN and leads science operations and education and outreach for the mission.
During its time at Mars, MAVEN has made the following discoveries and science results, among others:
- Acquired compelling evidence that the loss of atmosphere to space has been a major driver of climate change on Mars.
- Determined that the stripping of ions from the upper atmosphere to space during a solar storm can be enhanced by a factor of 10 or more, possibly making these storms .
- Discovered two new types of Martian aurorae: diffuse aurora and . Neither type has a direct connection to the local or global magnetic field or to magnetic cusps, as aurorae do on Earth.
- Made direct , the first direct detection of such a layer on any planet other than the Earth. The ions are produced by a steady influx of incoming interplanetary dust.
- Demonstrated that the majority of the carbon dioxide on Mars has been lost to space, and that there isn’t enough left to terraform the planet by warming it, even if the carbon dioxide could be released and put back into the atmosphere.
Next year, engineers will initiate an aerobraking maneuver by skimming the spacecraft through Mars’ upper atmosphere to slow it down. This will reduce the highest altitude in MAVEN’s orbit to enhance its ability to serve as a communications relay for data from rovers on the surface. Currently, MAVEN carries out about one relay pass per week with one of the rovers. This number will increase after NASA’s lands on Mars in November.
MAVEN completed its primary mission in November 2015 and has been operating in an extended mission since that time, continuing its productive investigation of Mars’ upper atmosphere and exploring additional opportunities for science that the new relay orbit will bring.
NASA’s Goddard Space Flight Center in Greenbelt, Maryland, manages the MAVEN project and provided two science instruments for the mission. Lockheed Martin built the spacecraft and is responsible for mission operations. The University of California, Berkeley’s Space Sciences Laboratory also provided four science instruments for the mission. NASA’s Jet Propulsion Laboratory in Pasadena, California, provides navigation and Deep Space Networksupport, as well as the Electra telecommunications relay hardware and operations.