From the lab to the moon: Lunar cement alternative survives 6 months on ISS and returned stronger in some tests
Building material samples from the University of Delaware spent six months mounted outside the International Space Station, where the harsh conditions of low Earth orbit tested their limits.
Some returned with higher measured strength than identical samples stored on Earth. The findings are a promising sign for the long-term goal of building infrastructure on the moon. There are no lunar supply yards, and transporting building materials from Earth would be prohibitively expensive. The solution may lie underfoot, in the form of lunar dust known as regolith.
"Regolith is essentially a clay-like silicate material," said Norman Wagner, Unidel Robert L. Pigford Chair in chemical engineering. "It is one of the most abundant materials on both Earth and the moon, which makes it interesting for construction."
Wagner's laboratory develops geopolymers, a cement alternative that binds clays into a strong solid through chemical reactions rather than high-temperature manufacturing. The goal is to use regolith with minimal additives to produce construction materials without energy-intensive processing. The approach could contribute to more sustainable Earth-based construction, too.
To evaluate how geopolymers hold up in space, the UD team sent thin plates made from commercially available simulated lunar and Martian regolith to the International Space Station as part of NASA's MISSE-20 mission.
The findings, published in Advances in Space Research, showed the geopolymers did not deteriorate, and in some cases were stronger after their time in orbit.
Lunar construction materials must not only survive space conditions, they also must be reliably manufactured onsite. In a separate study in Acta Astronautica, Wagner's team used artificial intelligence to tackle a practical challenge: Not all lunar clays are the same.
The researchers developed a machine-learning model that can predict how strong a geopolymer will be based on the characteristics of the starting regolith and how it is processed.
Complementary work from the Wagner lab offers insight into how geopolymers behave while being mixed, pumped and shaped before they harden. The researchers identified a key transition point, known as the critical gel point, at which the material shifts from a workable slurry into a solidifying structure. Mixing or shearing before that point did not affect how long the material took to harden or its final strength. This suggests engineers may have flexibility in how they handle and process lunar construction materials without compromising quality.
That work appears in a special issue of the Journal of Rheology focused on materials behavior beyond Earth.
Publication details
Thaddeus M. Egnaczyk et al, Effects of low-earth orbit exposure on geopolymer material properties, Advances in Space Research (2026). DOI: 10.1016/j.asr.2026.02.080
William H. Hartt V et al, Predicting lunar regolith simulant geopolymer compressive strength via machine learning, Acta Astronautica (2026). DOI: 10.1016/j.actaastro.2026.06.035
Olfa D'Angelo et al, Rheology beyond Earth, Journal of Rheology (2026). DOI: 10.1122/8.0001216
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Citation: From the lab to the moon: Lunar cement alternative survives 6 months on ISS and returned stronger in some tests (2026, July 8) retrieved 13 July 2026 from https://phys.org/news/2026-07-lab-moon-lunar-cement-alternative.html
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