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Sep 3, 2020

Quest to colonize space demands boost from biotechnology, synthetic biology

Posted by in categories: bioengineering, biotech/medical, space travel

Over the last 12,000 years or so, human civilization has noticeably reshaped the Earth’s surface. But changes on our own planet will likely pale in comparison when humans settle on other celestial bodies. While many of the changes on Earth over the centuries have been related to food production, by way of agriculture, changes on other worlds will result, not only from the need for on-site production of food, but also for all other consumables, including air.

As vital as synthetic biology will be to the early piloted missions to Mars and voyages of exploration, it will become indispensable to establish a long-term human presence off-Earth, namely colonization. That’s because we’ve evolved over billions of years to thrive specifically in the environments provided by our home planet.

Our physiology is well-suited to Earth’s gravity and its oxygen-rich atmosphere. We also depend on Earth’s global magnetic field to shield us from intense space radiation in the form of charged particles. In comparison, Mars has only patches of localized magnetism, thought to be remnants of a global magnetic field in the distant past. Currently, the Red Planet has no global magnetic field that could trap particle radiation from interplanetary space. Also, the Martian atmosphere is so thin that any shielding against space radiation of any kind is minor compared with the protection that Earth’s atmosphere affords. At the Martian surface, atmospheric pressure never gets above 7 millibars. That’s like Earth at an altitude of about 27,000 m (89,000 ft), which is almost the edge of space. And while the moon’s proximity to Earth could make it a better location than Mars for the first off-world colony, the lunar radiation environment is similar to that of Mars.

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