What If We Could Build a Mars Base… Using Mars Itself?
Imagine sprawling Martian colonies, gleaming cities sculpted from the red planet’s own dust, habitats shimmering under a thin, ochre sky – a vision frequently painted by science fiction. From the resourcefulness of Mark Watney in The Martian to the ambitious terraforming projects of Red Planet, the idea of humans building a self-sustaining civilization on Mars has captivated imaginations for decades. But transforming this fantasy into reality requires overcoming immense logistical hurdles, the most significant being the exorbitant cost and complexity of transporting building materials from Earth. Now, a groundbreaking study published in iScience offers a potential solution, bringing us closer to the reality of those sci-fi dreams.
Scientists from the Xinjiang Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, have achieved a remarkable feat: they’ve successfully created strong, continuous fibers directly from a simulated Martian soil. This “Martian fiber,” with a tensile strength reaching 1320 MPa and an elastic modulus of 99 GPa, rivals the strength of some high-performance Earth-based materials. The process involves melting a Martian soil simulant – a material meticulously crafted to mimic the composition of actual Martian regolith – at high temperatures and then spinning it into fibers, much like creating glass fibers from molten glass.
When making glass fibers, you heat sand (silica) until it melts into a liquid. Then, you pull it through a tiny hole to create thin strands that cool and solidify into fibers. It’s similar here, except instead of sand, they used the Martian simulant. They used AI to predict the exact temperature needed to melt the simulant (1360°C), then melted it and pulled it through a tiny nozzle to create fibers.
The researchers experimented with different speeds of pulling the molten simulant. They found that pulling it slowly resulted in stronger fibers. This is because slower pulling gives the atoms in the fiber more time to arrange themselves in a more tightly packed, stronger structure. In contrast, faster pulling resulted in weaker fibers because the atoms didn’t have enough time to organize properly. This is analogous to slowly cooling molten glass to create a stronger, less brittle product. The resulting fibers were then analyzed for strength and durability. The process is called melt-drawing. The use of platinum-rhodium in the spinneret is due to its high melting point and inertness, preventing contamination of the fiber.
A single thread of such Martian fiber is only one-third the diameter of a human hair, yet it boasts twice the strength of a steel fiber of comparable size. Furthermore, it exhibits excellent corrosion resistance and extreme temperature tolerance. This means Martian soil fiber could be an ideal building material for constructing a Martian base.
The key to this success lies in the soil’s composition. Rich in silica and iron oxides, the simulant proved surprisingly suitable for fiber production. Interestingly, the higher iron content in the Martian fiber contributes to a denser, stronger structure than typical basalt fibers produced on Earth. Advanced techniques, including Raman spectroscopy and neutron scattering, were used to analyze the fiber’s structure, confirming its exceptional strength and density.
However, the fibers aren’t a standalone building material; they function like rebar, needing a matrix like concrete. Bundles of Martian fibers are immersed in a bonding agent to create a composite, subsequently 3D-printed into custom building components.
Moreover, the matrix material can also be sourced in situ on Mars. Loose Martian soil can be transformed into a relatively stable solid by adding a binder or applying high pressure. While this material alone lacks significant strength, incorporating Martian fibers creates a high-strength composite.
This achievement directly addresses a critical challenge in Martian colonization. Transporting building materials across interplanetary distances is prohibitively expensive and logistically complex. Producing materials in situ, or on-site, using ISRU (In-Situ Resource Utilization) techniques is essential for making a Martian base economically and practically viable. The Martian fiber can serve as a crucial reinforcement material in composites, potentially creating stronger and more durable structures for habitats, landing pads, and other essential infrastructure.
China’s Tianwen-3 mission, planned for around 2028, aims to return Martian samples. The differences between Earth and Mars—gravity, atmosphere—demand innovative manufacturing processes and equipment. Much work remains before practical application.
While challenges remain – such as scaling up production and adapting the process to the harsh Martian environment – this breakthrough represents a significant leap towards establishing a permanent human presence on Mars.
While Martian construction is still a future goal, this research shows immense potential. The technology could also find its application here on Earth. The research team’s ongoing work with basalt fiber has expanded its use; for instance, basalt-polymer composites create high-strength materials for applications like tank, ship, and aircraft armor.
Tom Mallard
Joined the Academy, to add using antennas for most structure between or one-side can stru ture preforms my guess strong as concrete_n_steel having tension bt melt + it’s a tiny space-frame structurally, here in USA it doesn’t ring a bell.
Anonymous
As an architect following ISRU and a member of a lunar mission, non-govt, found NASA baked lunar dirt in a microwave oven into a brick, it melts btw grains not a lava. Took it from there works on any dirt, did a landing pad 10m deep × 200m with two tiny 6-leg took 1500hrs. For handling micrometeorites 40cm of lunar soil on the roof, shades gamma handy. For more @tmallard on 𝕏