Tag Archives: space colonization

should we intentionally seed life on other planets?

Some bacteria have been found surviving on the outside of the International Space Station. Tardigrades are an even hardier form of microbe that can supposedly survive even close to absolute zero. They can essentially go dormant in a state very, very near death, then bounce back if and when they find themselves in suitable conditions later on. There is even speculation that life on Earth could have arrived from space in a form like this, and/or life forms originating on Earth could be living on other planets right now.

Space dust collisions as a planetary escape mechanism (In press Astrobiology, 2017)

Hypervelocity space dust is a unique entity in planetary systems like our Solar System, which is able to go past and enter the atmosphere of planets, collect samples of those planets and deposit samples of other planets. The entire system of fast space dust in a planetary system thus contains the atoms, molecules and possibly even microbial life, from all the planets and provides a means to mix them up amongst the different planets. For collecting atoms and molecules that form atmospheres, the mechanism proposed in this paper is fairly straightforward. For collecting life and life related molecules this mechanism has interesting features, but many detailed issues would still need to be studied. The violent collisions involved in this mechanism could make it difficult for life to remain intact. There are several possible collision scenarios that would all need to be explored to get a definitive answer to this problem. But even if life itself does not remain intact, it could still permit the complex molecules associated with life to get propelled into space, and that is also interesting for the panspermia process. Since space dust is ubiquitous all over the Solar System and is believed to exist in interstellar and probably intergalactic space, the mechanism proposed in this paper for propelling small particles into space could provide a universal mechanism both for the exchange of the atomic and molecular constituents between distant planetary atmospheres and for initiating the first step of the panspermia process.

According to Wikipedia, panspermia is “the hypothesis that life exists throughout the Universe, distributed by meteoroidsasteroidscomets,[1] planetoids,[2] and also by spacecraft in the form of unintended contamination by microorganisms.”

Of course there is still the Fermi Paradox – if life is so common, why haven’t we been able to find any evidence of it, anywhere, even once? There are ethical implications of all this. We would like to perpetuate our human species and current form of civilization, of course, and that means getting into space eventually. But if we don’t manage to pull that off, and all life on Earth is wiped out for one reason or another, panspermia means that life exists elsewhere, and somewhere, sometime, intelligent life will evolve again if it hasn’t already. But if there is absolutely no life anywhere else in the universe, the loss of it on Earth would mean the end of all life forever. That would be too heavy a burden to bear, and would mean we have a strong ethical obligation to get some self-sustaining human colonies out into space as an insurance policy. But there could be a cheaper form of insurance policy – intentionally contaminate space and nearby planets with hardy germs from Earth, and in a few billion years something will survive and evolve, somewhere, into something. Do this enough and again, eventually you will have intelligent life somewhere. But finally, if it turns out there is life on other nearby planets, even very primitive life, then intentionally contaminating them with our germs would not seem like such an ethical thing to do after all.

more on NASA’s plans

sciencealert.com has a little more on NASA’s plans to visit Mars around the early 2030s or so.

As NASA’s Greg Williams explained this week at the Humans to Mars Summit in Washington DC, the Moon mission is on the slate for 2027 and could see a crew spending a year sailing above the lunar surface.

That extended stay in space would be preceded by at least five missions, some manned and some unmanned, to lug bits of equipment towards the Moon. That kit would include a habitat for crew members as well as the Deep Space Transport spacecraft that NASA has in the works to take people all the way to Mars.

“If we could conduct a year-long crewed mission on this Deep Space Transport in cislunar space, we believe we will know enough that we could then send this thing, crewed, on a 1,000-day mission to the Mars system and back,” Williams said, as reported by Calla Cofield at Space.com.

what NASA is up to

NASA is working on a couple interesting things, The “space launch system” is described as “the world’s most powerful rocket“, with the aim of lifting components that can eventually be assembled into vehicles for deep space exploration. That’s right, we’re talking about a spaceship, about a decade out or so.

For those destinations farther into the solar system, including Mars, NASA envisions a deep space transport spacecraft. This spacecraft would be a reusable vehicle that uses electric and chemical propulsion and would be specifically designed for crewed missions to destinations such as Mars. The transport would take crew out to their destination, return them back to the gateway, where it can be serviced and sent out again. The transport would take full advantage of the large volumes and mass that can be launched by the SLS rocket, as well as advanced exploration technologies being developed now and demonstrated on the ground and aboard the International Space Station.

This second phase will culminate at the end of the 2020s with a one year crewed mission aboard the transport in the lunar vicinity to validate the readiness of the system to travel beyond the Earth-moon system to Mars and other destinations, and build confidence that long-duration, distant human missions can be safely conducted with independence from Earth. Through the efforts to build this deep space infrastructure, this phase will enable explorers to identify and pioneer innovative solutions to technical and human challenges discovered or engineered in deep space.

 

Buzz Aldrin’s plan for Mars

Buzz Aldrin has a plan to go to Mars.

Establishing private outposts in LEO [Low Earth Orbit] is just the first step in Aldrin’s plan for Mars colonization, which depends heavily on “cyclers” — spacecraft that move continuously between two cosmic destinations, efficiently delivering people and cargo back and forth…

Step two involves the international spaceflight community coming together to build cyclers that ply cislunar space, taking people on trips to the moon and back. Such spacecraft, and the activities they enable, would allow the construction of a crewed lunar base, where humanity could learn and test the techniques required for Mars colonization, such as how to manufacture propellant from local resources, Aldrin said…

Aldrin foresees these various cycler iterations enabling a crewed mission to a near-Earth asteroid by 2020 and a Venus flyby by 2024. If all goes well, the first future Mars settlers could launch in the early 2030s, he said.

So a sustainable Mars colony could be not an ambitious goal for the next 100 years, as Stephen Hawking just suggested, but 20 years or so out.

Stephen Hawking: escape the planet in 100 years

From The Independent:

In “Expedition New Earth” – a documentary that debuts this summer as part of the BBC’s “Tomorrow’s World” science season – Hawking claims that Mother Earth would greatly appreciate it if we could gather our belongings and get out – not in 1,000 years, but in the next century or so…

“Professor Stephen Hawking thinks the human species will have to populate a new planet within 100 years if it is to survive,” the BBC said with a notable absence of punctuation marks in a statement posted online. “With climate change, overdue asteroid strikes, epidemics and population growth, our own planet is increasingly precarious…”

The BBC program gives Hawking a chance to wade into the evolving science and technology that may become crucial if humans hatch a plan to escape Earth and find a way to survive on another planet – from questions about biology and astronomy to rocket technology and human hibernation, the BBC notes.

Getting a colony started on Mars, Earth’s moon, or another moon in the nearby solar system within a hundred years doesn’t seem all that daunting to me. Whether it could be truly self-sufficient from Earth in that time frame is the real question. That seems like a tall order, considering how much our current civilization depends on this planet’s natural gifts to get by. Our technology would have to improve a lot.

skyscraper hanging from an asteroid

Here’s an idea for a skyscraper hanging from an asteroid. It’s a twist on the old space elevator idea because it doesn’t actually touch the ground. First, you have to go out, catch the asteroid, and put it in the right position in orbit. Then, you build the thing. Then, once you’re in the thing it takes you on a wild ride all over the world every 24 hours.

radiation during your flight to Mars

Radiation exposure could be a problem on flights to Mars, according to Nature.

Cosmic radiation exposure and persistent cognitive dysfunction

The Mars mission will result in an inevitable exposure to cosmic radiation that has been shown to cause cognitive impairments in rodent models, and possibly in astronauts engaged in deep space travel. Of particular concern is the potential for cosmic radiation exposure to compromise critical decision making during normal operations or under emergency conditions in deep space. Rodents exposed to cosmic radiation exhibit persistent hippocampal and cortical based performance decrements using six independent behavioral tasks administered between separate cohorts 12 and 24 weeks after irradiation. Radiation-induced impairments in spatial, episodic and recognition memory were temporally coincident with deficits in executive function and reduced rates of fear extinction and elevated anxiety. Irradiation caused significant reductions in dendritic complexity, spine density and altered spine morphology along medial prefrontal cortical neurons known to mediate neurotransmission interrogated by our behavioral tasks. Cosmic radiation also disrupted synaptic integrity and increased neuroinflammation that persisted more than 6 months after exposure. Behavioral deficits for individual animals correlated significantly with reduced spine density and increased synaptic puncta, providing quantitative measures of risk for developing cognitive impairment. Our data provide additional evidence that deep space travel poses a real and unique threat to the integrity of neural circuits in the brain.

Elon Musk’s new spaceship

Here’s a video from Space X on their vision for a ship that can go to Mars and back as soon as 2025:

According to KurzweilAI:

In a talk on Tuesday at the International Astronautical Congress in Guadalajara, Mexico, SpaceX CEO Elon Musk laid out engineering details to establish a permanent, self-sustaining civilization of a million people on Mars, with an initial flight as soon as 2024.

SpaceX is designing a massive reusable Interplanetary Transport System spacecraft with cabins. The trip would initially cost $500,000 per person, with a long-term goal of 100 passengers per trip.

Musk plans to make humanity a “multiplanetary species” to ensure survival in case of a calamity like an asteroid strike. “This is really about minimizing existential risk and having a tremendous sense of adventure,” he said.

“artificial rainforest” in Dubai

I continue to think that places like Dubai and Singapore with extremely inhospitable climates are preparing humanity for its future in space. They are creating cities that consist of climate-controlled high rise apartments, office buildings, malls, and indoor parks, all connected by subway lines, so there is really no reason to go outside. It’s not too hard to imagine transferring one of these cities to Mars.