6. Mining on the Moon

Annotation: Modern research into technologies for extracting mineral resources on the Moon has revealed some harsh limitations related to dependence on Earth’s resources and high technological requirements. While the chemical and carbothermal reduction of lunar regolith is theoretically possible, it requires a constant supply of reducing agents such as hydrogen or carbon from Earth. This signifi cantly increases mission costs and complicates logistics, making such methods unsuitable for large-scale applications. Pyrolysis, which involves heating regolith to extremely high temperatures, is also not an optimal solution due to the need for complex and energy-intensive equipment that exceeds the capabilities of current space technologies. Electrolysis using molten fl uoride salts or calcium chloride (CaCl2 ) has been proposed as an alternative, but its effi ciency is limited by the need to deliver fl uxes from Earth. This reduces the autonomy of the process and makes it less economically viable in the long term. In light of these limitations, the most promising technology appears to be the direct electrolysis of molten regolith, which stands out for its simplicity and independence from terrestrial materials. This method involves melting local raw materials, followed by electrolytic separation into useable components such as oxygen, metal alloys, and other materials. However, the key challenge to implementing this technology is the development of refractory conductive materials for anodes that can withstand the extreme conditions of high temperatures and aggressive oxygen environments. Existing materials degrade rapidly under these factors, leading to reduced effi ciency and increased maintenance costs. Additionally, reliable protective coatings for equipment must be developed to prevent corrosion and mechanical wear. Overcoming these technical challenges would enable the creation of an autonomous lunar resource extraction system, which is critical for future lunar bases and further space exploration. Such a system could provide astronauts with oxygen, water, and construction materials without constant supplies from Earth, signifi cantly reducing the cost of space missions. Thus, despite existing technological challenges, direct electrolysis remains the most viable option for the industrial use of local lunar resources. Further research should focus on optimizing materials and application methods, as well as on developing energy-effi cient solutions to ensure the stability and economic feasibility of lunar mining. This will open new possibilities for a sustained human presence on the Moon and will be a signifi cant step in deep space exploration.