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It is interesting to note that the technical possibility to send interstellar Ark appeared in 1960th, and is based on the concept of “Blust-ship” of Ulam. This blast-ship uses the energy of nuclear explosions to move forward. Detailed calculations were carried out under the project “Orion”. http://en.wikipedia.org/wiki/Project_Orion_(nuclear_propulsion) In 1968 Dyson published an article “Interstellar Transport”, which shows the upper and lower bounds of the projects. In conservative (ie not imply any technical achievements) valuation it would cost 1 U.S. GDP (600 billion U.S. dollars at the time of writing) to launch the spaceship with mass of 40 million tonnes (of which 5 million tons of payload), and its time of flight to Alpha Centauri would be 1200 years. In a more advanced version the price is 0.1 U.S. GDP, the flight time is 120 years and starting weight 150 000 tons (of which 50 000 tons of payload). In principle, using a two-tier scheme, more advanced thermonuclear bombs and reflectors the flying time to the nearest star can reduce to 40 years.
Of course, the crew of the spaceship is doomed to extinction if they do not find a habitable and fit for human planet in the nearest star system. Another option is that it will colonize uninhabited planet. In 1980, R. Freitas proposed a lunar exploration using self-replicating factory, the original weight of 100 tons, but to control that requires artificial intelligence. “Advanced Automation for Space Missions” http://www.islandone.org/MMSG/aasm/ Artificial intelligence yet not exist, but the management of such a factory could be implemented by people. The main question is how much technology and equipment should be enough to throw at the moonlike uninhabited planet, so that people could build on it completely self-sustaining and growing civilization. It is about creating something like inhabited von Neumann probe. Modern self-sustaining state includes at least a few million people (like Israel), with hundreds of tons of equipment on each person, mainly in the form of houses, roads. Weight of machines is much smaller. This gives us the upper boundary of the able to replicate human colony in the 1 billion tons. The lower estimate is that there would be about 100 people, each of which accounts for approximately 100 tons (mainly food and shelter), ie 10 000 tons of mass. A realistic assessment should be somewhere in between, and probably in the tens of millions of tons. All this under the assumption that no miraculous nanotechnology is not yet open.
The advantage of a spaceship as Ark is that it is non-specific reaction to a host of different threats with indeterminate probabilities. If you have some specific threat (the asteroid, the epidemic), then there is better to spend money on its removal.
Thus, if such a decision in the 1960th years were taken, now such a ship could be on the road.
But if we ignore the technical side of the issue, there are several trade-offs on strategies for creating such a spaceship.
1. The sooner such a project is started, the lesser technically advanced it would be, the lesser would be its chances of success and higher would be cost. But if it will be initiated later, the greater would be chances that it will not be complete until global catastrophe.
2. The later the project starts, the greater are the chance that it will take “diseases” of mother civilization with it (e.g. ability to create dangerous viruses ).
3. The project to create a spaceship could lead to the development of technologies that threaten civilization itself. Blast-ship used as fuel hundreds of thousands of hydrogen bombs. Therefore, it can either be used as a weapon, or other party may be afraid of it and respond. In addition, the spaceship can turn around and hit the Earth, as star-hammer — or there maybe fear of it. During construction of the spaceship could happen man-made accidents with enormous consequences, equal as maximum to detonation of all bombs on board. If the project is implementing by one of the countries in time of war, other countries could try to shoot down the spaceship when it launched.
4. The spaceship is a means of protection against Doomsday machine as strategic response in Khan style. Therefore, the creators of such a Doomsday machine can perceive the Ark as a threat to their power.
5. Should we implement a more expensive project, or a few cheaper projects?
6. Is it sufficient to limit the colonization to the Moon, Mars, Jupiter’s moons or objects in the Kuiper belt? At least it can be fallback position at which you can check the technology of autonomous colonies.
7. The sooner the spaceship starts, the less we know about exoplanets. How far and how fast the Ark should fly in order to be in relative safety?
8. Could the spaceship hide itself so that the Earth did not know where it is, and should it do that? Should the spaceship communicate with Earth? Or there is a risk of attack of a hostile AI in this case?
9. Would not the creation of such projects exacerbate the arms race or lead to premature depletion of resources and other undesirable outcomes? Creating of pure hydrogen bombs would simplify the creation of such a spaceship, or at least reduce its costs. But at the same time it would increase global risks, because nuclear non-proliferation will suffer complete failure.
10. Will the Earth in the future compete with its independent colonies or will this lead to Star Wars?
11. If the ship goes off slowly enough, is it possible to destroy it from Earth, by self-propelling missile or with radiation beam?
12. Is this mission a real chance for survival of the mankind? Flown away are likely to be killed, because the chance of success of the mission is no more than 10 per cent. Remaining on the Earth may start to behave more risky, in logic: “Well, if we have protection against global risks, now we can start risky experiments.” As a result of the project total probability of survival decreases.
13. What are the chances that its computer network of the Ark will download the virus, if it will communicate with Earth? And if not, it will reduce the chances of success. It is possible competition for nearby stars, and faster machines would win it. Eventually there are not many nearby stars at distance of about 5 light years — Alpha Centauri, the Barnard star, and the competition can begin for them. It is also possible the existence of dark lonely planets or large asteroids without host-stars. Their density in the surrounding space should be 10 times greater than the density of stars, but to find them is extremely difficult. Also if nearest stars have not any planets or moons it would be a problem. Some stars, including Barnard, are inclined to extreme stellar flares, which could kill the expedition.
14. The spaceship will not protect people from hostile AI that finds a way to catch up. Also in case of war starships may be prestigious, and easily vulnerable targets — unmanned rocket will always be faster than a spaceship. If arks are sent to several nearby stars, it does not ensure their secrecy, as the destination will be known in advance. Phase transition of the vacuum, the explosion of the Sun or Jupiter or other extreme event can also destroy the spaceship. See e.g. A.Bolonkin “Artificial Explosion of Sun. AB-Criterion for Solar Detonation” http://www.scribd.com/doc/24541542/Artificial-Explosion-of-Sun-AB-Criterion-for-Solar-Detonation
15. However, the spaceship is too expensive protection from many other risks that do not require such far removal. People could hide from almost any pandemic in the well-isolated islands in the ocean. People can hide on the Moon from gray goo, collision with asteroid, supervolcano, irreversible global warming. The ark-spaceship will carry with it problems of genetic degradation, propensity for violence and self-destruction, as well as problems associated with limited human outlook and cognitive biases. Spaceship would only burden the problem of resource depletion, as well as of wars and of the arms race. Thus, the set of global risks from which the spaceship is the best protection, is quite narrow.
16. And most importantly: does it make sense now to begin this project? Anyway, there is no time to finish it before become real new risks and new ways to create spaceships using nanotech.
Of course it easy to envision nano and AI based Ark – it would be small as grain of sand, carry only one human egg or even DNA information, and could self-replicate. The main problem with it is that it could be created only ARTER the most dangerous period of human existence, which is the period just before Singularity.

For any assembly or structure, whether an isolated bunker or a self sustaining space colony, to be able to function perpetually, the ability to manufacture any of the parts necessary to maintain, or expand, the structure is an obvious necessity. Conventional metal working techniques, consisting of forming, cutting, casting or welding present extreme difficulties in size and complexity that would be difficult to integrate into a self sustaining structure.

Forming requires heavy high powered machinery to press metals into their final desired shapes. Cutting procedures, such as milling and lathing, also require large, heavy, complex machinery, but also waste tremendous amounts of material as large bulk shapes are cut away emerging the final part. Casting metal parts requires a complex mold construction and preparation procedures, not only does a negative mold of the final part need to be constructed, but the mold needs to be prepared, usually by coating in ceramic slurries, before the molten metal is applied. Unless thousands of parts are required, the molds are a waste of energy, resources, and effort. Joining is a flexible process, and usually achieved by welding or brazing and works by melting metal between two fixed parts in order to join them — but the fixed parts present the same manufacturing problems.

Ideally then, in any self sustaining structure, metal parts should be constructed only in the final desired shape but without the need of a mold and very limited need for cutting or joining. In a salient progressive step toward this necessary goal, NASA demonstrates the innovative Electron Beam Free Forming Fabrication (http://www.aeronautics.nasa.gov/electron_beam.htm) Process. A rapid metal fabrication process essentially it “prints” a complex three dimensional object by feeding a molten wire through a computer controlled gun, building the part, layer by layer, and adding metal only where you desire it. It requires no molds and little or no tooling, and material properties are similar to other forming techniques. The complexity of the part is limited only by the imagination of the programmer and the dexterity of the wire feed and heating device.

Electron beam freeform fabrication process in action
Electron beam freeform fabrication process in action

According to NASA materials research engineer Karen Taminger, who is involved in developing the EBF3 process, extensive simulations and modeling by NASA of long duration space flights found no discernable pattern to the types of parts which failed, but the mass of the failed parts remained remarkably consistent throughout the studies done. This is a favorable finding to in-situe parts manufacturing and because of this the EBF³ team at NASA has been developing a desktop version. Taminger writes:

“Electron beam freeform fabrication (EBF³) is a cross-cutting technology for producing structural metal parts…The promise of this technology extends far beyond its applicability to low-cost manufacturing and aircraft structural designs. EBF³ could provide a way for astronauts to fabricate structural spare parts and new tools aboard the International Space Station or on the surface of the moon or Mars”

NASA’s Langley group working on the EBF3 process took their prototype desktop model for a ride on the microgravity simulating NASA flight and found the process works just fine even in micro gravity, or even against gravity.

A structural metal part fabricated from EBF³
A structural metal part fabricated from EBF³

The advantages this system offers are significant. Near net shape parts can be manufactured, significantly reducing scrap parts. Unitized parts can be made — instead of multiple parts that need riveting or bolting, final complex integral structures can be made. An entire spacecraft frame could be ‘printed’ in one sitting. The process also creates minimal waste products and is highly energy and feed stock efficient, critical to self sustaining structures. Metals can be placed only where they are desired and the material and chemistry properties can be tailored through the structure. The technical seminar features a structure with a smooth transitional gradient from one alloy to another. Also, structures can be designed specifically for their intended purposes, without needing to be tailored to manufacturing process, for example, stiffening ridges can be curvilinear, in response to the applied forces, instead of typical grid patterns which facilitate easy conventional manufacturing techniques. Manufactures, such as Sciaky Inc, (http://www.sciaky.com/64.html) are all ready jumping on the process

In combination with similar 3D part ‘printing’ innovations in plastics and other materials, the required complexity for sustaining all the mechanical and structural components of a self sustaining structure is plummeting drastically. Isolated structures could survive on a feed stock of scrap that is perpetually recycled as worn parts are replaced by free form manufacturing and the old ones melted to make new feed stock. Space colonies could combine such manufacturing technologies and scrap feedstock with resource collection creating a viable minimal volume and energy consuming system that could perpetually repair the structure – or even build more. Technologies like these show that the atomic level control that nanotechnology manufacturing proposals offer are not necessary to create self sustaining structure, and that with minor developments of modern technology, self sustaining structures could be built and operated successfully.

Many years ago, in December 1993 to be approximate, I noticed a space-related poster on the wall of Eric Klien’s office in the headquarters of the Atlantis Project. We chatted for a bit about the possibilities for colonies in space. Later, Eric mentioned that this conversation was one of the formative moments in his conception of the Lifeboat Foundation.

Another friend, filmmaker Meg McLain has noticed that orbital hotels and space cruise liners are all vapor ware. Indeed, we’ve had few better depictions of realistic “how it would feel” space resorts since 1968’s Kubrick classic “2001: A Space Odyssey.” Remember the Pan Am flight to orbit, the huge hotel and mall complex, and the transfer to a lunar shuttle? To this day I know people who bought reservation certificates for whenever Pan Am would begin to fly to the Moon.

In 2004, after the X Prize victory, Richard Branson announced that Virgin Galactic would be flying tourists by 2007. So far, none.

A little later, Bigelow announced a fifty million dollar prize if only tourists could be launched to orbit by January 2010. I expect the prize money won’t be claimed in time.

Why? Could it be that the government is standing in the way? And if tourism in space can’t be “permitted” what of a lifeboat colony?

Meg has set out to make a documentary film about how the human race has arrived four decades after the Moon landing and still no tourist stuff. Two decades after Kitty Hawk, a person could fly across the country; three decades, across any ocean.

Where are the missing resorts?

Here is the link to her film project:
http://www.freewebs.com/11at40/

Jim Davies of Strike the Root writes about Galt’s Gulch and some gulch-like projects. These appeal to him because of the exponential trends in government power and abuse of power. He writes, in part,

“We have the serious opportunity in our hands right now of terminating the era of government absolutely, and so of removing from the human race the threat of ever more brutal tyranny ending only with WMD annihilation–while opening up vistas of peaceful prosperity and technological progress which even a realist like myself cannot find words to describe. ”

http://www.strike-the-root.com/91/davies/davies11.html

Avoiding those terrible events is what building our Lifeboat is all about. Got Lifeboat?

It sounds like cryonics is working, at least for microbes. But could any humans now alive have resistance to ancient organisms?

Rational Review carried a link to this story:

http://www.foxnews.com/story/0,2933,526460,00.html

“After more than 120,000 years trapped beneath a block of ice in Greenland, a tiny microbe has awoken. … The new bacteria species was found nearly 2 miles (3 km) beneath a Greenland glacier, where temperatures can dip well below freezing, pressure soars, and food and oxygen are scarce. ‘We don’t know what state they were in,’ said study team member Jean Brenchley of Pennsylvania State University. ‘They could’ve been dormant, or they could’ve been slowly metabolizing, but we don’t know for sure.’”

It is yet another interesting possibility against which humans should prepare to protect ourselves. Where is our Lifeboat?

The projected size of Barack Obama’s “stimulus package” is heading north, from hundreds of billions of dollars into the trillions. And the Obama program comes, of course, on top of the various Bush administration bailouts and commitments, estimated to run as high as $8.5 trillion.

Will this money be put to good use? That’s an important question for the new President, and an even more important question for America. The metric for all government spending ultimately comes down to a single query: What did you get for it?

If such spending was worth it, that’s great. If the country gets victory in war, or victory over economic catastrophe, well, obviously, it was worthwhile. The national interest should never be sacrificed on the altar of a balanced budget.

So let’s hope we get the most value possible for all that money–and all that red ink. Let’s hope we get a more prosperous nation and a cleaner earth. Let’s also hope we get a more secure population and a clear, strategic margin of safety for the United States. Yet how do we do all that?

There’s only one best way: Put space exploration at the center of the new stimulus package. That is, make space the spearhead rationale for the myriad technologies that will provide us with jobs, wealth, and vital knowhow in the future. By boldly going where no (hu)man has gone before, we will change life here on earth for the better.

To put it mildly, space was not high on the national agenda during 2008. But space and rocketry, broadly defined, are as important as ever. As Cold War arms-control theology fades, the practical value of missile defense–against superpowers, also against rogue states, such as Iran, and high-tech terrorist groups, such as Hezbollah and Hamas–becomes increasingly obvious. Clearly Obama agrees; it’s the new President, after all, who will be keeping pro-missile defense Robert Gates on the job at the Pentagon.

The bipartisan reality is that if missile offense is on the rise, then missile defense is surely a good idea. That’s why increasing funding for missile defense engages the attention of leading military powers around the world. And more signs appear, too, that the new administration is in that same strategic defense groove. A January 2 story from Bloomberg News, headlined “Obama Moves to Counter China With Pentagon-NASA Link,” points the way. As reported by Demian McLean, the incoming Obama administration is looking to better coordinate DOD and NASA; that only makes sense: After all, the Pentagon’s space expenditures, $22 billion in fiscal year 2008, are almost a third more than NASA’s. So it’s logical, as well as economical, to streamline the national space effort.

That’s good news, but Obama has the opportunity to do more. Much more.

Throughout history, exploration has been a powerful strategic tool. Both Spain and Portugal turned themselves into superpowers in the 15th and 16th century through overseas expansion. By contrast, China, which at the time had a technological edge over the Iberian states, chose not to explore and was put on the defensive. Ultimately, as we all know, China’s retrograde policies pushed the Middle Kingdom into a half-millennium-long tailspin.

Further, we might consider the enormous advantages that England reaped by colonizing a large portion of the world. Not only did Britain’s empire generate wealth for the homeland, albeit often cruelly, but it also inspired technological development at home. And in the world wars of the 20th century, Britain’s colonies, past and present, gave the mother country the “strategic depth” it needed for victory.

For their part, the Chinese seem to have absorbed these geostrategic lessons. They are determined now to be big players in space, as a matter of national grand strategy, independent of economic cycles. In 2003, the People’s Republic of China powered its first man into space, becoming only the third country to do so. And then, more ominously, in 2007, China shot down one of their own weather satellites, just to prove that they had robust satellite-killing capacity.

Thus the US and all the other space powers are on notice: In any possible war, the Chinese have the capacity to “blind” our satellites. And now they plan to put a man on the moon in the next decade. “The moon landing is an extremely challenging and sophisticated task,” declared Wang Zhaoyao, a spokesman for China’s space program, in September, “and it is also a strategically important technological field.”

India, the other emerging Asian superpower, is paying close attention to its rival across the Himalayas. Back in June, The Washington Times ran this thought-provoking headline: “China, India hasten arms race in space/U.S. dominance challenged.” According to the Times report, India, possessor of an extensive civilian satellite program, means to keep up with emerging space threats from China, by any means necessary. Army Chief of Staff Gen. Deepak Kapoor said that his country must “optimize space applications for military purposes,” adding, “the Chinese space program is expanding at an exponentially rapid pace in both offensive and defensive content.” In other words, India, like every other country, must compete–because the dangerous competition is there, like it or not.

India and China have fought wars in the past; they obviously see “milspace” as another potential theater of operations. And of course, Japan, Russia, Brazil, and the European Union all have their own space programs.

Space exploration, despite all the bonhomie about scientific and economic benefit for the common good, has always been driven by strategic competition. Beyond mere macho “bragging rights” about being first, countries have understood that controlling the high ground, or the high frontier, is a vital military imperative. So we, as a nation, might further consider the value of space surveillance and missile defense. It’s hard to imagine any permanent peace deal in the Middle East, for example, that does not include, as an additional safeguard, a significant commitment to missile and rocket defense, overseen by impervious space satellites. So if the U.S. and Israel, for example, aren’t there yet, well, they need to get there.

Americans, who have often hoped that space would be a demilitarized preserve for peaceful cooperation, need to understand that space, populated by humans and their machines, will be no different from earth, populated by humans and their machines. That is, every virtue, and every evil, that is evident down here will also be evident up there. If there have been, and will continue to be, arms races on earth, then there will be arms races in space. As we have seen, other countries are moving into space in a big way–and they will continue to do so, whether or not the U.S. participates.

Meanwhile, in the nearer term, if the Bush administration’s “forward strategy of freedom”–the neoconservative idea that we would make America safe by transforming the rest of the world–is no longer an operative policy, then we will, inevitably, fall back on “defense” as the key idea for making America safe.

But in the short run, of course, the dominant issue is the economy. Aside from the sometimes inconvenient reality that national defense must always come first, the historical record shows that high-tech space work is good for the economy; the list of spinoffs from NASA, spanning the last half-century, is long and lucrative.

Moreover, a great way to guarantee that the bailout/stimulus money is well spent is to link it to a specific goal–a goal which will in turn impose discipline on the spenders. During the New Deal, for example, there were many accusations of malfeasance against FDR’s “alphabet soup” of agencies, and yet the tangible reality, in the 30s, was that things were actually getting done. Jobs were created, and, just as more important, enduring projects were being built; from post offices to Hoover Dam to the Tennessee Valley Authority, America was transformed.

Even into the 50s and 60s, the federal government was spending money on ambitious and successful projects. The space program was one, but so was the interstate highway program, as well as that new government startup, ARPANET.

Indeed, it could be argued that one reason the federal government has grown less competent and more flabby over the last 30 years is the relative lack of “hard” Hamiltonian programs–that is, nuts and bolts, cement and circuitry–to provide a sense of bottom-line rigor to the spending process.

And so, for example, if America were to succeed in building a space elevator–in its essence a 22,000-mile cable, operating like a pulley, dangling down from a stationary satellite, a concept first put forth in the late 19th century–that would be a major driver for economic growth. Japan has plans for just such a space elevator; aren’t we getting a little tired of losing high-tech economic competitions to the Japanese?

So a robust space program would not only help protect America; it would also strengthen our technological economy.

But there’s more. In the long run, space spending would be good for the environment. Here’s why:

History, as well as common sense, tells us that the overall environmental footprint of the human race rises alongside wealth. That’s why, for example, the average American produces five times as much carbon dioxide per year as the average person dwelling anywhere else on earth. Even homeless Americans, according to an MIT study–and even the most scrupulously green Americans–produce twice as much CO2, per person, as the rest of the world. Around the planet, per capita carbon dioxide emissions closely track per capita income.

A holistic understanding of homo sapiens in his environment will acknowledge the stubbornly acquisitive and accretive reality of human nature. And so a truly enlightened environmental policy will acknowledge another blunt reality: that if the carrying capacity of the earth is finite, then it makes sense, ultimately, to move some of the population of the earth elsewhere–into the infinity of space.

The ZPG and NPG advocates have their own ideas, of course, but they don’t seem to be popular in America, let alone the world. But in the no-limits infinity of space, there is plenty of room for diversity and political experimentation in the final frontier, just as there were multiple opportunities in centuries past in the New World. The main variable is developing space-traveling capacity to get up there–to the moon, Mars, and beyond–to see what’s possible.

Instead, the ultimately workable environmental plan–the ultimate vision for preserving the flora, the fauna, and the ice caps–is to move people, and their pollution, off this earth.

Indeed, space travel is surely the ultimate plan for the survival of our species, too. Eventually, through runaway WMD, or runaway pollution, or a stray asteroid, or some Murphy-esque piece of bad luck, we will learn that our dominion over this planet is fleeting. That’s when we will discover the grim true meaning of Fermi’s Paradox.

In various ways, humankind has always anticipated apocalypse. And so from Noah’s Ark to “Silent Running” to “Wall*E,” we have envisioned ways for us and all other creatures, great and small, to survive. The space program, stutteringly nascent as it might be, can be seen as a slow-groping understanding that lifeboat-style compartmentalization, on earth and in the heavens, is the key to species survival. It’s a Darwinian fitness test that we ought not to flunk.

Barack Obama, who has blazed so many trails in his life, can blaze still more, including a track to space, over the far horizon of the future. In so doing, he would be keeping faith with a figure that he in many ways resembles, John F. Kennedy. It was the 35th President who declared that not only would America go to the moon, but that we would lead the world into space.

As JFK put it so ringingly back in 1962:

The vows of this Nation can only be fulfilled if we in this Nation are first, and, therefore, we intend to be first. In short, our leadership in science and in industry, our hopes for peace and security, our obligations to ourselves as well as others, all require us to make this effort, to solve these mysteries, to solve them for the good of all men, and to become the world’s leading space-faring nation.

Today the 44th President must spend a lot of money to restore our prosperity, but he must spend it wisely. He must also keep America secure against encroaching threats, even as he must improve the environment in the face of a burgeoning global economy.

Accomplishing all these tasks is possible, but not easy. Yes, of course he will need new ideas, but he will also need familiar and proven ideas. One of the best is fostering and deploying profound new technology in pursuit of expansion and exploration.

The stars, one might hope, are aligning for just such a rendezvous with destiny.

Here I would like to suggest readers a quotation from my book “Structure of the global catastrophe” (http://www.scribd.com/doc/7529531/-) there I discuss problems of preventing catastrophes.

Refuges and bunkers

Different sort of a refuge and bunkers can increase chances of survival of the mankind in case of global catastrophe, however the situation with them is not simple. Separate independent refuges can exist for decades, but the more they are independent and long-time, the more efforts are necessary for their preparation in advance. Refuges should provide ability for the mankind to the further self-reproduction. Hence, they should contain not only enough of capable to reproduction people, but also a stock of technologies which will allow to survive and breed in territory which is planned to render habitable after an exit from the refuge. The more this territory will be polluted, the higher level of technologies is required for a reliable survival.
Very big bunker will appear capable to continue in itself development of technologies and after catastrophe. However in this case it will be vulnerable to the same risks, as all terrestrial civilisation — there can be internal terrorists, AI, nanorobots, leaks etc. If the bunker is not capable to continue itself development of technologies it, more likely, is doomed to degradation.
Further, the bunker can be or «civilizational», that is keep the majority of cultural and technological achievements of the civilisation, or “specific”, that is keep only human life. For “long” bunkers (which are prepared for long-term stay) the problem of formation and education of children and risks of degradation will rise. The bunker can or live for the account of the resources which have been saved up before catastrophe, or be engaged in own manufacture. In last case it will be simply underground civilisation on the infected planet.
The more a bunker is constructed on modern technologies and independent cultural and technically, the higher ammount of people should live there (but in the future it will be not so: the bunker on the basis of advanced nanotechnology can be even at all deserted, — only with the frozen human embryos). To provide simple reproduction by means of training to the basic human trades, thousand people are required. These people should be selected and be in the bunker before final catastrophe, and, it is desirable, on a constant basis. However it is improbable, that thousand intellectually and physically excellent people would want to sit in the bunker “just in case”. In this case they can be in the bunker in two or three changes and receive for it a salary. (Now in Russia begins experiment «Mars 500» in which 6 humans will be in completely independent — on water, to meal, air — for 500 days. Possibly, it is the best result which we now have. In the early nineties in the USA there was also a project «Biosphera-2» in which people should live two years on full self-maintenance under a dome in desert. The project has ended with partial failure as oxygen level in system began to fall because of unforeseen reproduction of microorganisms and insects.) As additional risk for bunkers it is necessary to note fact of psychology of the small groups closed in one premise widely known on the Antarctic expeditions — namely, the increase of animosities fraught with destructive actions, reducing survival rate.
The bunker can be either unique, or one of many. In the first case it is vulnerable to different catastrophes, and in the second is possible struggle between different bunkers for the resources which have remained outside. Or is possible war continuation if catastrophe has resulted from war.
The bunker, most likely, will be either underground, or in the sea, or in space. But the space bunker too can be underground of asteroids or the Moon. For the space bunker it will be more difficult to use the rests of resources on the Earth. The bunker can be completely isolated, or to allow “excursion” in the external hostile environment.
As model of the sea bunker can serve the nuclear submarine possessing high reserve, autonomy, manoeuvrability and stability to negative influences. Besides, it can easily be cooled at ocean (the problem of cooling of the underground closed bunkers is not simple), to extract from it water, oxygen and even food. Besides, already there are ready boats and technical decisions. The boat is capable to sustain shock and radiating influence. However the resource of independent swimming of modern submarines makes at the best 1 year, and in them there is no place for storage of stocks.
Modern space station ISS could support independently life of several humans within approximately year though there are problems of independent landing and adaptation. Not clearly, whether the certain dangerous agent, capable to get into all cracks on the Earth could dissipate for so short term.
There is a difference between gaso — and bio — refuges which can be on a surface, but are divided into many sections for maintenance of a mode of quarantine, and refuges which are intended as a shelter from in the slightest degree intelligent opponent (including other people who did not manage to get a place in a refuge). In case of biodanger island with rigid quarantine can be a refuge if illness is not transferred by air.
A bunker can possess different vulnerabilities. For example, in case of biological threat, is enough insignificant penetration to destroy it. Only hi-tech bunker can be the completely independent. Energy and oxygen are necessary to the bunker. The system on a nuclear reactor can give energy, but modern machines hardly can possess durability more than 30–50 years. The bunker cannot be universal — it should assume protection against the certain kinds of threats known in advance — radiating, biological etc.
The more reinforced is a bunker, the smaller number of bunkers can prepare mankind in advance, and it will be more difficult to hide such bunker. If after a certain catastrophe there was a limited number of the bunkers which site is known, the secondary nuclear war can terminate mankind through countable number of strikes in known places.
The larger is the bunker, the less amount of such bunkers is possible to construct. However any bunker is vulnerable to accidental destruction or contamination. Therefore the limited number of bunkers with certain probability of contamination unequivocally defines the maximum survival time of mankind. If bunkers are connected among themselves by trade and other material distribution, contamination between them is more probable. If bunkers are not connected, they will degrade faster. The more powerfully and more expensively is the bunker, the more difficult is to create it imperceptibly for the probable opponent and so it easeir becomes the goal for an attack. The more cheaply the bunker, the less it is durable.
Casual shelters — the people who have escaped in the underground, mines, submarines — are possible. They will suffer from absence of the central power and struggle for resources. The people, in case of exhaustion of resources in one bunker, can undertake the armed attempts to break in other next bunker. Also the people who have escaped casually (or under the threat of the comong catastrophe), can attack those who was locked in the bunker.
Bunkers will suffer from necessity of an exchange of heat, energy, water and air with an external world. The more independent is the bunker, the less time it can exist in full isolation. Bunkers being in the Earth will deeply suffer from an overheating. Any nuclear reactors and other complex machines will demand external cooling. Cooling by external water will unmask them, and it is impossible to have energy sources lost-free in the form of heat, while on depth of earth there are always high temperatures. Temperature growth, in process of deepening in the Earth, limits depth of possible bunkers. (The geothermal gradient on the average makes 30 degrees C/kilometers. It means, that bunkers on depth more than 1 kilometre are impossible — or demand huge cooling installations on a surface, as gold mines in the republic of South Africa. There can be deeper bunkers in ices of Antarctica.)
The more durable, more universal and more effective, should be a bunker, the earlier it is necessary to start to build it. But in this case it is difficult to foresee the future risks. For example, in 1930th years in Russia was constructed many anti-gase bombproof shelters which have appeared useless and vulnerable to bombardments by heavy demolition bombs.
Efficiency of the bunker which can create the civilisation, corresponds to a technological level of development of this civilisation. But it means that it possesses and corresponding means of destruction. So, especially powerful bunker is necessary. The more independently and more absolutely is the bunker (for example, equipped with AI, nanorobots and biotechnologies), the easier it can do without, eventually, people, having given rise to purely computer civilisation.
People from different bunkers will compete for that who first leaves on a surface and who, accordingly, will own it — therefore will develop the temptation for them to go out to still infected sites of the Earth.
There are possible automatic robotic bunkers: in them the frozen human embryos are stored in a certain artificial uterus and through hundreds or thousand years start to be grown up. (Technology of cryonics of embryos already exists, and works on an artificial uterus are forbidden for bioethics reasons, but basically such device is possible.) With embryos it is possible to send such installations in travel to other planets. However, if such bunkers are possible, the Earth hardly remains empty — most likely it will be populated with robots. Besides, if the human cub who has been brought up by wolves, considers itself as a wolf as whom human who has been brought up by robots will consider itself?
So, the idea about a survival in bunkers contains many reefs which reduce its utility and probability of success. It is necessary to build long-term bunkers for many years, but they can become outdated for this time as the situation will change and it is not known to what to prepare. Probably, that there is a number of powerful bunkers which have been constructed in days of cold war. A limit of modern technical possibilities the bunker of an order of a 30-year-old autonomy, however it would take long time for building — decade, and it will demand billions dollars of investments.
Independently there are information bunkers, which are intended to inform to the possible escaped descendants about our knowledge, technologies and achievements. For example, in Norway, on Spitsbergen have been created a stock of samples of seeds and grain with these purposes (Doomsday Vault). Variants with preservation of a genetic variety of people by means of the frozen sperm are possible. Digital carriers steady against long storage, for example, compact discs on which the text which can be read through a magnifier is etched are discussed and implemented by Long Now Foundation. This knowledge can be crucial for not repeating our errors.

November 14, 2008
Computer History Museum, Mountain View, CA

http://ieet.org/index.php/IEET/eventinfo/ieet20081114/

Organized by: Institute for Ethics and Emerging Technologies, the Center for Responsible Nanotechnology and the Lifeboat Foundation

A day-long seminar on threats to the future of humanity, natural and man-made, and the pro-active steps we can take to reduce these risks and build a more resilient civilization. Seminar participants are strongly encouraged to pre-order and review the Global Catastrophic Risks volume edited by Nick Bostrom and Milan Cirkovic, and contributed to by some of the faculty for this seminar.

This seminar will precede the futurist mega-gathering Convergence 08, November 15–16 at the same venue, which is co-sponsored by the IEET, Humanity Plus (World Transhumanist Association), the Singularity Institute for Artificial Intelligence, the Immortality Institute, the Foresight Institute, the Long Now Foundation, the Methuselah Foundation, the Millenium Project, Reason Foundation and the Accelerating Studies Foundation.

SEMINAR FACULTY

  • Nick Bostrom Ph.D., Director, Future of Humanity Institute, Oxford University
  • Jamais Cascio, research affiliate, Institute for the Future
  • James J. Hughes Ph.D., Exec. Director, Institute for Ethics and Emerging Technologies
  • Mike Treder, Executive Director, Center for Responsible Nanotechnology
  • Eliezer Yudkowsky, Research Associate. Singularity Institute for Artificial Intelligence
  • William Potter Ph.D., Director, James Martin Center for Nonproliferation Studies

REGISTRATION:
Before Nov 1: $100
After Nov 1 and at the door: $150

This is cross-posted from my blog. This milestone by SpaceX is directly relevant to programs by Lifeboat such as the AsteroidShield and SpaceHabitat, and possibly also (eventually) to Space-Based Solar Power.

SpaceX Falcon 1 Rocket Launch photo

Stars My Destination
After the third try, Elon Musk, the founder of SpaceX, co-founder of Paypal, chairman of SolarCity and chairman of Tesla Motors (beat that resumé!) was interviewed by WIRED about the difficulties of making his space rockets reach orbit:

Wired.com: How do you maintain your optimism?

Musk: Do I sound optimistic?

Wired.com: Yeah, you always do.

Musk: Optimism, pessimism, fuck that; we’re going to make it happen. As God is my bloody witness, I’m hell-bent on making it work.

Falcon 1: The First Privately Developed Rocket to Orbit the Earth
Well kids, perseverance pays off. On the 4th try, the 70-foot Falcon 1 rocket reached orbit wit a 364-pound dummy payload: “The data shows we achieved a super precise orbit insertion — middle of the bullseye — and then went on to coast and restart the second stage, which was icing on the cake.” Check out the video of the highlights of the launch.

“This really means a lot,” Musk told a crowd of whooping employees. “There’s only a handful of countries on Earth that have done this. It’s usually a country thing, not a company thing. We did it.”

Musk pledged to continue getting rockets into orbit, saying the company has resolved design issues that plagued previous attempts.

Last month, SpaceX lost three government satellites and human ashes including the remains of astronaut Gordon Cooper and “Star Trek” actor James Doohan after its third rocket was lost en route to space. The company blamed a timing error for the failure that caused the rocket’s first stage to bump into the second stage after separation.

SpaceX’s maiden launch in 2006 failed because of a fuel line leak. Last year, another rocket reached about 180 miles above Earth, but its second stage prematurely shut off.

The Falcon 1, at $7.9 million each, is what you could call the budget model. In fact, $7.9 million is basically pocket changed compared to what government agencies like NASA are used to paying to contractors like Lockheed Martin & co.

SpaceX is also working on the Falcon 9 (12,500 kg to low Earth orbit, and over 4,640 kg to geosynchronous transfer orbit) and Falcon 9 Heavy (28,000 kg to low Earth orbit, and over 12,000 kg to geosynchronous transfer orbit) to help NASA reach the International Space Station, among other things. These should cost between $36.75 million and $104 million each depending on the model and mission, and the first launch is scheduled for the first quarter of 2009.

Continue reading “SpaceX Falcon 1 Rocket Reaches Orbit on 4th Try” | >