Hope is constructing a diurnal picture of Mars' atmosphere for the first time.
The Emirates Mars Mission, the first interplanetary exploration undertaken by an Arab nation, has triggered a rush of new observations, discoveries and insights into Mars unique atmosphere, composition and dynamics.
With key announcements already made including new and startling observations of Mars discrete aurora and unprecedented views of dayside oxygen and carbon monoxide structures in the planets atmosphere, new avenues of exploration are now being opened up by the slew of data being brought back from the Hope spacecraft.
Commenting on the development, Hessa Al Matroushi, Emirates Mars Mission Science Lead, said: “The success of Hope is already assured from our early results and observations and we can already see a vast number of new potential avenues of exploration opening up as a result of our early data. We are seeing Mars in remarkable detail and are able to characterise the diurnal behaviours of Mars atmosphere for the first time ever. The potential we are now seeing from the mission undoubtedly exceeds our expectations.”
Papers and posters being shared and presented at the AGU21 Fall Meeting in New Orleans reflect the unique picture of Mars atmosphere being built by EMMs Hope Probe, with a combination of Hopes advanced instrumentation and smart elliptical orbit providing new views of the Martian atmosphere at all times through the day, night and seasons of the Red Planet.
Christopher S Edwards, EMIRS Instrument Lead, added: “The ability of EMM to observe Mars at all local times on short timescales enables the daily variation of these clouds to be studied. The EMIRS observations show that clouds are thickest and cover the most area early in the morning and late in the evening with fewer clouds near midday. The comparison of clouds observed by EMIRS at thermal-infrared wavelengths to those observed by EXI at visible wavelengths can provide further information about the clouds, such as size of the water ice aerosols that make up the clouds.”
Michael Wolff, EXI Instrument Lead stated: “As on the earth, clouds on Mars are an important part of the water cycle and characterising how they change from hour-to-hour and day-to-day is an important part in understanding both the present and past climates.”
Hope set out to measure the global, diurnal and seasonal response of the Martian atmosphere to solar forcing; the atmospheric conditions relating to the rate of atmospheric escape particularly of Hydrogen and Oxygen and the temporal and spatial behaviour of Mars exosphere. With early results showing exciting observations of Mars discrete aurora and additional bandwidth and resources available to encompass additional observations, further measurements of auroral phenomena have been brought into the missions goals, extending its capabilities beyond Hopes planned goals.
Mars Hope carries three instruments; the Emirates eXploration Imager (EXI) digital camera, which captures images of Mars with a resolution of two to four km along with measuring the amount of water ice and ozone in the lower atmosphere through the UV bands; the Emirates Mars InfraRed Spectrometer (EMIRS), which measures the emitted energy from the martian surface and atmosphere, deriving the global distribution of dust, ice cloud, and water vapor in the Martian lower atmosphere, and the Emirates Mars Ultraviolet Spectrometer (EMUS), which measures oxygen and carbon monoxide in the thermosphere and the variability of hydrogen and oxygen in the exosphere.
MM Deputy Science Lead and EMUS Instrument Lead Justin Deighan noted: “By comparing the images of hydrogen that we gain from the EMUS instrument to the maps of water ice, water vapor, and dust acquired by the EXI and EMIRS instruments, scientists will be able to reconstruct the details of how hydrogen is transported through the Martian atmosphere and how water has been lost from the planet over the history of the Solar System. Thanks to the uniquely large orbit of the Hope probe around Mars, the instruments on the Hope probe are able to view the planet from different points of view across all times of day, bringing powerful new insights to our understanding of Mars atmospheric dynamics.”
The Missions Hope Probe is following its planned 20,000 43,000 km elliptical science orbit, with an inclination to Mars of 25 degrees, giving it a unique ability to complete one orbit of the planet every 55 hours and capture a full planetary data sample every nine days throughout its one Martian year (two Earth year) mission to map Mars atmospheric dynamics.