Breathing a sigh of relief on Mars - the next Mars rover will carry a device for producing oxygen

NASA's Mars 2020 mission will also operate a facility that will produce oxygen from the carbon dioxide gas in the atmosphere in preparation for a future manned flight. Itai Nebo also reviews the other missions planned for Mars, including the private mission MARS ONE

The US space agency has already landed four spacecraft on the surface of Mars. All of them were engaged in research tasks: searching for water and signs of life, photographing the surface, analyzing the composition of the soil, geological research and examination of the composition of the atmosphere. NASA's next Mars rover, whose launch is planned for 2020, should for the first time not only engage in passive research of the existing one, but also conduct an experiment with a unique instrument, which will be the first real step towards flying humans to the red planet. The vehicle, meanwhile, is known by its original name Mars The 2020 Rover will carry with it a device for extracting oxygen from the gases present in the thin atmosphere of Mars.

air to breath

The device known as MOXIE (more or less an acronym for: Mars OXygen In situ resource utilization Experiment, i.e. 'an experiment in the utilization of resources to produce oxygen on Mars'), was developed at the Massachusetts Institute of Technology (MIT). The device is actually an inverted fuel cell. A normal fuel cell uses fuel and an oxidizer to produce energy. As mentioned, MOXIE will do the process in the opposite direction: it will invest energy in producing oxygen from fuel materials. In this case the fuel is carbon dioxide, the main component (96%) of the Martian atmosphere. Each molecule of carbon dioxide (CO2), contains two oxygen atoms and the investment of energy in its decomposition should yield oxygen molecules (O2), which we need for breathing.

If the MOXIE experiment is successful, NASA will be able to build a larger system to supply oxygen to the crew members who will one day arrive on Mars. Moreover, MIT says that using the system on a large scale will also make it possible to produce liquid oxygen, which is used as rocket fuel, and will provide Possibility of launching spacecraft from Mars back to Earth. "I imagine the following scenario," says the head of the research team, Prof. Michael Hecht from MIT. Arriving on Mars, they have both air to breathe and fuel that will allow them to return home." According to Hecht, overcoming the need to bring the oxygen to Mars would reduce 75% of the volume and weight of the manned mission there, and would also relieve NASA of the need to carry out a complex mission, such as dropping a frozen oxygen container separately on Mars.

World chemistry

MOXIE is one of seven devices that the American space agency chose this week for the next Mars rover, out of 58 proposals sent to it by scientists from all over the world. They are mainly intended for exploring the planet's surface with more sophisticated instruments than those available to previous Mars rovers. The other six devices are:

• SuperCam - a sophisticated laser camera designed for chemical analysis of soil composition, developed at Los Alamos laboratories in collaboration with the French Institute of Astrophysics.
• Mastcam-Z - an improved panoramic camera with focusing capability, which allows to investigate with great precision the nature of the minerals on the surface.
• PIXL - a spectrometer (a device for analyzing chemical composition) that works with X-rays, and is supposed to analyze the elements that make up different substances. The device was developed at the University of Arizona.
• SHERLOC – a different type of spectrometer that works with ultraviolet (UV) radiation. The device developed in the NASA laboratories is mainly intended for the detection of organic substances in the soil, which may indicate signs of the existence of life in the present or in the past.
• MEDA - a device for measuring environmental parameters developed at the Technological Institute of Spain, and includes sensors for temperature, humidity, wind speed and direction as well as the amount of dust and the characterization of its particles.
• RIMFAX - a ground penetrating radar developed at the Forskning Institute in Norway, and intended for the study of geological features of Mars below the surface, at extremely high levels of accuracy.

"We are pleased that the Mars 2020 rover will demonstrate our capabilities to produce pure oxygen from the abundant carbon dioxide," said James Reuther, deputy director of the Mars Program in NASA's Space Technology Mission Directorate. "This technology demonstration will pave The way to cheap manned missions to Mars where oxygen will be required for life support and rocket propulsion."

Tools developed from the selected proposals will be applied to a space vehicle similar to Curiosity which is currently on Mars, thus saving the development of a new platform, while increasing confidence that the system will operate.

Crowded, but far away

Mars 2020 Rover will be NASA's fifth Mars rover. It was preceded by two Viking landers that landed on Mars in 1976 (and were not mobile after landing) and the Sojourner all-terrain vehicles that landed on Mars as part of the Pathfinder mission in 1997; Spirit and Opportunity that landed in -2004 (Both were supposed to last three months: Spirit operated for more than five years, Opportunity continues to operate to this day, and days ago Ahadim broke the record for travel across a celestial gram outside the Earth, when he completed a journey of more than 40 km);

In the coming years, the European Space Agency plans to launch two more research vehicles to Mars: Insight, intended for geological research at great depth, scheduled for launch in 2016, and ExoMars, scheduled for launch two years later. It is being developed in cooperation with Russia (which is mainly responsible for the landing system), and its main task will be to search for signs of life on Mars, which of course can also provide guidance for the existence of organic materials, and the elements necessary for sustaining life there today, and for the production of materials necessary for manned missions.

Despite the much expected activity on the surface of Mars, it is doubtful that a human foot will set foot there in less than twenty years. Even though man is getting closer and closer to the technological capabilities needed to accomplish such an achievement, at least in the foreseeable future, no entity will be willing to undertake the financing of such an expensive venture. The Mars 2020 Rover mission will cost nearly two billion dollars. A manned mission would be several orders of magnitude more expensive, certainly if the plan included returning the crew to Earth. The only way to realize the dream of a manned landing on Mars, will probably be a large-scale global cooperation, which may also include the establishment of an intermediate station on the moon, from where it is much easier to launch large spacecraft, due to the weak gravity.

Meanwhile, by the way, a private entrepreneur in the Netherlands decided to start his own program, MarsOne. According to this plan, 24 volunteers will be flown to Mars (in six spaceships with four astronauts) starting in 2024, and a manned colony will be established without the ability to return to Earth. More than 200,000 people signed up for the program, and after initial selections, about 700 candidates remained eight Israelis). It is very doubtful whether a private body will be able to meet the financial challenge of the mission, without the extensive cooperation of countries with money and technology. Landing a man on Mars is still far away, but maybe if the MOXIE experiment is successful, the whole project will get a little more air to breathe.