Atmospheric loss Mars loses water into its thin atmosphere by evaporation. There, solar radiation can split the water molecules into their components,
hydrogen and
oxygen. The hydrogen, as the lightest element, then tends to rise far up to the highest levels of the
Martian atmosphere, where several processes can strip it away into space, to be forever lost to the planet. This loss was thought to proceed at a fairly constant rate, but MAVEN's observations of Mars's atmospheric hydrogen through a full Martian year (almost two Earth years) show that the escape rate is highest when Mars's orbit brings it closest to the
Sun, and only one-tenth as great when it is at its farthest. On 5 November 2015,
NASA announced that data from MAVEN shows that the deterioration of Mars's atmosphere increases significantly during
solar storms. That loss of atmosphere to space likely played a key role in Mars's gradual shift from its
carbon dioxide-dominated atmosphere—which had kept Mars relatively warm and allowed the planet to support liquid surface water—to the cold, arid planet seen today. This shift took place between about 4.2 and 3.7 billion years ago. The atmospheric loss was especially notable during an interplanetary
coronal mass ejection in March 2015.
Different types of aurora In 2014, MAVEN researchers detected widespread
auroras throughout the planet, even close to the equator. Given the localized magnetic fields on Mars (as opposed to Earth's global magnetic field), auroras appear to form and distribute in different ways on Mars, creating what scientists call diffuse auroras. Researchers determined that the source of the particles causing the auroras were a huge surge of electrons originating from the Sun. These highly energetic particles were able to penetrate far deeper into Mars's atmosphere than they would have on Earth, creating auroras much closer to the surface of the planet (~60 km as opposed to 100–500 km on Earth). Scientists also discovered proton auroras, different from the so-called typical auroras which are produced by electrons. Proton auroras were previously only detected on Earth.
Interaction with a comet The fortuitous arrival of MAVEN just before a flyby of the comet
C/2013 A1 (Siding Spring) gave researchers a unique opportunity to observe both the comet itself as well as its interactions with the Martian atmosphere. The spacecraft's IUVS instrument detected intense ultraviolet emissions from magnesium and iron ions, a result from the comet's meteor shower, which were much stronger than anything ever detected on Earth. The NGIMS instrument was able to directly sample dust from this
Oort cloud comet, detecting at least eight different types of metal ions.
Detection of metal ions In 2017, results were published detailing the detection of metal ions in Mars's ionosphere. This was the first time metal ions were detected in any planet's atmosphere other than Earth's. It was also noted that these ions behave and are distributed differently in the atmosphere of Mars given that the red planet has a much weaker magnetic field than our own.
Impacts on future exploration In September 2017, NASA reported a temporary doubling of
radiation levels on the surface of Mars, as well as an
aurora 25 times brighter than any observed earlier. This occurred due to a massive, and unexpected,
solar storm. The observation provided insight into how changes in radiation levels might impact the planet's habitability, helping NASA researchers understand how to predict as well as mitigate effects on future human Mars explorers. == Communication loss ==