colonized

Humanity has between an eyebrow and an eyebrow to reach Mars and eventually plant a colony there. Missions like NASA’s Curiosity rover have been scanning its surface for years for signs of past habitability (with promising findings that leave big unknowns) and the program Artemis II It is the technological springboard towards the first manned mission to Mars. Sooner or later there will come a day when humanity sets foot on Mars and the conditions to inhabit it are met (or manufactured). So the next question will be: how do we make a house there? It’s not so much a question of design, but of survival. A research team is already working on it and believes they have the solution, which they have published in the journal Frontiers in Microbiology. The concept. The research work from Politecnico di Milano, the University of Central Florida and Jiangsu University consists of using two bacteria that work together: one is capable of surviving in extreme conditions and produces oxygen and the other that turns human urine into stone. This promising duo is capable of manufacturing bricks directly from the Martian soil, without the need for kilns, factories or bringing materials from Earth. Why it is important. Because from an engineering point of view, moving materials and machinery over long distances (as long as going to Mars) makes the cost skyrocket and becomes technically unfeasible. Furthermore, building them with the materials available on Mars is not (yet) an option. So this concept solves those two problems and some others, such as energy consumption. According to the paperbiocementation consumes up to 7 times less energy than melting soil with microwaves and almost 50 times less than thermal sintering. Finally, because it is convenient: it converts human metabolic waste into construction material, thus solving the logistical problem of what to do with that waste. Context. Because the different space agencies have the arrival to Mars in the 2030-2040 decade on their roadmap. Biocementation (microbiologically induced calcium carbonate precipitation) has been under study for two decades for uses such as stabilize soils, stop desertification either build with less carbon dioxide. This research transfers this knowledge to space and has its applications on Earth in the form of more sustainable construction, soil repair or self-healing concrete. chow they did it. This point is essential because the research team has neither built anything on Mars nor in the laboratory, using real regolith. This is a perspective paper, reviewing the known knowledge about this technique to provide a concept analyzing the Martian regolith from data from robotic missions. From that point and after identifying the deficiency of calcium oxide with respect to terrestrial cement, they have studied what biological routes can compensate for it. That’s where your proposal comes from, with the combination of Chroococcidiopsis + Sporosarcina pasteurii as the most promising, which is accompanied by a conceptual design of a bioreactor and 3D printing nozzle integrated with autonomous robotics. Yes, but. The previous point makes the first handicap clear: this combination of batteries has never been tested, neither on Mars nor in the laboratory. And on Mars the scenario is tricky: the reduced gravity weakens the microstructure of the resulting material (at least, conventional cement) and the perchlorates in the Martian soil are toxic to organisms. As if that were not enough, the temperature range in which bacteria can operate is narrow. Additionally, the water required may not be suitable. There is also no long-term stability data for this crop. If we talk about technological maturity, this project is in a primitive phase: a concept on paper financed with a long road ahead. In Xataka | China has found a “vital” element to colonize Mars: it resists in lethal conditions for other forms of life In Xataka | We have a serious problem in our plans to colonize Mars: the astronauts’ blood is mutating Cover | Rain Morales and Planet Volumes