Establishing a moon base will be critical for the U.S. in the new space race and building safe and cost-effective landing pads for spacecraft to touch down there will be key.
These pads will have to stop lunar dust and particles from sandblasting everything around them at more than 10,000 miles per hour as a rocket takes off or lands since there is no air to slow the rocket plume down.
However, how to build these landing pads is not so clear, as hauling materials and heavy equipment more than 230,000 miles into space quickly becomes cost prohibitive.
That鈥檚 why 麻豆原创 researchers are working on a NASA-funded project to find ways to build lunar landing pads that keep people and equipment safe but are also economical and easy to construct in space. The work is led by defense and space manufacturing company Cislune and includes research from Arizona State University.
The team has found that a method that uses microwaves to melt lunar soil, coupled with 麻豆原创-developed beneficiation, or sorting, technology, may be the best option.
The findings were published recently in the journal New Space and in a report submitted to NASA.
鈥淚t鈥檚 strategically important for our nation to have a presence on the moon because the economic value of the resources in space is very high,鈥 says Phil Metzger 鈥00MS 鈥05PhD, a co-author of the research. He is a planetary scientist at the based at 麻豆原创.
The U.S. plans to return to the moon as part of the Artemis missions, with the first crewed lunar landing expected to take place as part of Artemis III in 2025. Future missions will establish habitats, resource extraction equipment and more.
Based on an analysis of four different construction methods, including different combinations for inner and outer landing pad rings, a melting 鈥 or sintering鈥 method using microwaves was found to be the most cost effective as long as the cost of transportation to the moon remains above $100,000 per kilogram (about $45,000 a pound), according to the new study.
Sintering becomes even more economical when coupled with a new 麻豆原创-developed, beneficiation technology that uses magnetic fields to bring the most microwavable minerals to the surface. 麻豆原创 researchers designed the technology after discovering many of the most microwavable minerals are also the most magnetic. These findings were documented in the new report to NASA.
鈥淲e鈥檝e shown that we can increase microwave absorption by somewhere in the range of 70% to 80% by sorting particles based on magnetic susceptibility,鈥 Metzger says.
The construction process could be carried out by rovers that would scoop soil, sort it with magnetic fields, layer it back down to the surface, and melt it with microwaves, the researcher says.
The New Space study found that the second-most-cost-effective method when transportation costs are above $100,000 per kilogram would be paver-based landing pads.
Additionally, once transportation costs drop below $100,000 per kilogram, due to economies of scale and rocket reusability, polymer-based landing pads become a more competitive method for constructing the outer part of the landing pad than sintering and pavers.
Each of the methods have trade-offs, such as energy and construction costs, that must be considered, Metzger says.
鈥淭he numbers showed us that sintering is actually the best method because it does require some energy, but the cost of the energy is less than the cost of construction and having to bring consumables to the moon,鈥 Metzger says.
Erik Franks, founder and chief executive officer of Cislune, says surface construction on the moon and Mars are very different than construction on Earth.
鈥淐oncrete and steel are used extensively on Earth and have come about from millennia of development and scaling up of industry based upon plentiful water, coal and air,鈥 he says. 鈥淥n other planets we don鈥檛 have any fossil fuels, and air and water are more valuable than gold. Different processes will be required, and 麻豆原创 and Cislune are working together to solve these problems with innovative solutions like microwave sintering and soil beneficiation.鈥
The researchers used high-fidelity lunar soil simulants from 麻豆原创鈥檚 to perform the microwave and magnetic susceptibility experiments and used computer simulations to model the economic costs of different lunar landing pad construction methods.
For the lunar soil simulant experiments, basaltic glass, bronzite, and ilmenite were found to be some of the most magnetic and microwave susceptible minerals.
鈥淥ur results were excellent,鈥 Franks says. 鈥淐areful beneficiation makes microwave heating of regolith dramatically more energy efficient, so we just need to bring solar panels and can process the lunar dirt into structures like landing pads and buildings.鈥
Metzger says the research is not only important for establishing a U.S. presence on the moon but also for maintaining diplomatic relations by not sandblasting other countries鈥 equipment and facilities.
鈥淚 think it’s really crucial for the United States and a consortium of friendly countries that share our values for democracy to lead the way in space to set up methods of sharing space and set up pockets of benefiting the whole world from space, rather than just taking the risk of letting others do it,鈥 Metzger says.
The work was funded in part by the NASA Solar System Exploration Virtual Institute, the Center for Lunar and Asteroid Surface Science, and by the NASA Small Business Technology Transfer (STTR) program.
Next steps for the research include developing projects to create improved prototypes of the microwave heating hardware and to test the technology in moon-like conditions in a vacuum.
The co-author of New Science study was Greg Autry with the Thunderbird School of Global Management, Arizona State University. Dhaka Sapkota, an assistant scientist at FSI, led the magnetic beneficiation experiments and co-authored the beneficiation report.
Metzger received his bachelor鈥檚 degree in electrical engineering from Auburn University and his master鈥檚 and doctoral degree in physics from 麻豆原创. Before joining 麻豆原创 in 2014, he worked at NASA鈥檚 Kennedy Space Center for nearly 30 years.
Study title: The Cost of Lunar Landing Pads with a Trade Study of Construction Methods
