The vocabulary in this new book on Extraterrestrial Construction Techniques is amazing, from the design of “Earth-independent habitats” to the use of “space-native metals” and other “non-terrestrial construction materials in the alien environment of space.”
The full manuscript also contains a section on “high-fidelity simulants”—another great phrase—as well as one on artificial crystal-growth techniques in space. Here, the ideas themselves are architecturally evocative: “It is envisioned that fragments of bio-like materials could be launched in an inactive state during space flight, and once landed at the Moon or Mars, would start to grow into construction materials or even pre-engineered habitats.” Controlled crystal architecture!
You can easily imagine some new version of Jack and the Beanstalk, about a relentlessly growing crystal building, a future folktale for life in space.
Anyway, there was an amazing story last week suggesting that, deep inside the planet, minerals might exhibit flaws associated with “collisions with dark matter.” In a sense, this would make the entire interior of the earth a de facto dark matter detector—or, according to researchers at the University of Michigan, “minerals such as halite (sodium chloride) and zabuyelite (lithium carbonate), can act as ready-made detectors.”
Proving this hypothesis sounds like the opening scene of a blockbuster science fiction film: “An experiment could extract the minerals—which can be around 500 million years old—from kilometres-deep boreholes that already exist for geological research and oil prospecting. Physicists would need to crack open the extracted minerals and scan the exposed surfaces under an electron or atomic force microscope for the tracks made by recoiling nuclei. They could also use X-ray or ultraviolet 3D scanners to study bigger chunks of minerals faster, but with lower resolution.”
Meanwhile, ScienceDaily reported earlier this month that flaws deliberately introduced into the crystal forms of diamonds could be structured such that they improve those diamonds’ capacity for quantum computation. Apparently, a team at Princeton has designed new kinds of diamonds “that contain defects capable of storing and transmitting quantum information for use in a future ‘quantum internet.’”
There is obviously no connection between these two stories, but that won’t stop me from imagining some vast new quantum computer network, coextensive with the Earth’s interior, performing prime-number calculations along dark matter-induced crystal flaws, crooked mineral veins flashing in the darkness with data, like some buried circuitboard throbbing beneath the continents and seas.