Lifeboat Foundation: Safeguarding Humanity
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Category: space – Page 1,079

NASA’s Marshall Space Flight Center has designed a nuclear-warhead-carrying spacecraft, that would be boosted by the US agency’s proposed Ares V cargo launch vehicle, to deflect asteroids.

The Ares V launch vehicle is scheduled to first fly in 2018. It would launch 130 tons to LEO.

I welcome this study for providing a clearer analysis of the deflection options and the analyzing costs of searching for threatening asteroids.

The 8.9m (29ft)-long “Cradle” spacecraft would carry six 1,500kg (3,300lb) missile-like interceptor vehicles that would carry one 1.2MT B83 nuclear warhead each, with a total mass of 11,035kg.

99942 Apophis is a near-Earth asteroid that caused a brief period of concern in December 2004 because initial observations indicated a relatively large probability that it would strike the Earth in 2029. It is 350 meters across and weighs about 46 million tons.

The study team assessed a series of approaches that could be used to divert a NEO potentially on a collision course with Earth. Nuclear explosives, as well as non-nuclear options, were assessed.
• Nuclear standoff explosions are assessed to be 10–100 times more effective than the non-nuclear alternatives analyzed in this study. Other techniques involving the surface or subsurface use of nuclear explosives may be more efficient, but they run an increased risk of fracturing the target NEO. They also carry higher development and operations risks.
• Non-nuclear kinetic impactors are the most mature approach and could be used in some deflection/mitigation scenarios, especially for NEOs that consist of a single small, solid body.
• “Slow push” mitigation techniques are the most expensive, have the lowest level of technical readiness, and their ability to both travel to and divert a threatening NEO would be limited unless mission durations of many years to decades are possible.
• 30–80 percent of potentially hazardous NEOs are in orbits that are beyond the capability of current or planned launch systems. Therefore, planetary gravity assist swingby trajectories or on-orbit assembly of modular propulsion systems may be needed to augment launch vehicle performance, if these objects need to be deflected.


This diagram shows that the nuclear options work better and can handle asteroids up to 950 meters in size


This is a table that shows that a performance index of 1 means a method was good enough to perform a successful deflection. Less than 1 means more launches are needed.


This is a drawing of the deflection vehicle

The Lifeboat foundation has the asteroid shield program

The US-led effort to expand the military BMEWS (ballistic missile early warning radar system) to Poland and the Czech Republic provoke Russian military strategists. Putin has proposed using their already operative radar base in Azerbajian (See “Azeri radar eyed for US shield”, BBC) in exchange for information from the US system. The US/NATO proposed TMD (theater missile defense) will also integrate early warning systems for short-range missiles in southern Europe. Is the race for space awareness and the weaponization of space inevitable?

The justification for the missile shield is the potential threat of long range missiles from Iran and North Korea (See “N-Korea test fires missile”, BBC). Military experts predict that with the current progress of nuclear research and missile technology available to Iran they will pose a threat to the US in 2015. NATO and Russia co-operate in certain military matters through the Russia-Nato Council but has increasingly been in conflict over the Iranian nuclear program and the European missile shield. (See “Russia-NATO: A marriage of convenience”, RIA Novosti). Russia has also demonstrated the ineffectiveness of the missile shield by launching their RS-24 multiple missile system carrying 10 warheads (See “RS-24 Missiles to replace old systems within next few years”, Interfax).

Terrestrial radars need to be complemented by satellites to keep track of missile launches across the planet (so called “boost phase interceptors”, see “Missile defense, satellites and politics”, The Space Review) to ensure complete space awareness. The Chinese Space Agency tested an anti-satellite missile earlier this year (See “Pentagon says China’s anti-satellite test posed a threat to nations”, AP). The move towards a hot space war could be imminent. The official press release was the only information given from Chinese authorities. The secrecy surrounding space capabilities was recently challenged by French authorities when they discovered 20–30 unregistered US surveillance satellites. (See “French says ‘non’ to U.S. Disclosure of Secret Satellites”, Space.com).

The race for the control of space is threatening to destabilize established military power structures. Secrecy is not the way of solving imbalances in international relations. Space is a part of the “commons” and should be dealt with accordingly. I propose an open source approach to the space awareness problematique. There are several approaches to distributed space awareness, e.g. launching private satellites for surveillance and distribution of real-time satellite imagery in order to counter a military space race. The alternative is a UN led control organization like the IAEA.

Other organizations like the Lifeboat Foundation could also play an important role in developing a threat reduction system for the ongoing cold space war.

If humanity ever meets lifeforms beyond Earth (or discovers our solitude in our galaxy) one thing will be sure–galactic historians will remark how interesting it must have been living in the nuclear age that “we now enjoy” (assuming we survive of course).

Speaking of nuclear, it seems that some scientists are utilizing a new drug that is showing major promises of fighting against radiation exposure, ensuring that victims not only survive, but remain “semi-healthy” as well.

(Space War) But now researchers at Washington University School of Medicine in St. Louis report they have developed an agent that protects cells from the lethal effects of radiation, regardless of whether it is given before or after exposure.

Using this agent in mice, the investigators found that the treatment helped shield rapidly dividing cells that are most vulnerable to radiation-induced death, providing proof in principle that it is possible to fend off radiation damage, according to a study published in the April issue of Biochemical and Biophysical Research Communications.

The interesting aspect of this drug is that it can be applied not only before a potential radiation calamity, but afterwards as well. Despite the fact that this drug is intended for those living on our home world, this anti-radiation drug could enable us to actually live upon the lunar and Martian surface.

Although this drug is not a “cure all” for all of our radiation woes, it could represent the first step of us actually living upon other worlds.

Mathematician and science fiction author Vernor Vinge, who coined the term “Singularity”, is an advocate of the Lifeboat Foundation’s mission: get some people off the Earth and get them self-sustaining as soon as possible, as an insurance policy against existential risk. In his “What if the Singularity does not happen?” talk for the Long Now Foundation in San Francisco, Vinge calls the continuing pursuit of space under current-day launch costs as a “sham”:

Well, launch to LEO still runs $5000 to $10000/kg. As far as I can tell, the new Vision for Space Exploration will maintain these costs. This approach made some sense in 1970, when we were just beginning and when initial surveys of the problems and applications were worth almost any expense. Now, in the early 21st century, these launch costs make talk of humans-in-space a doubly gold-plated sham:

    • First, because of the pitiful limitations on delivered payloads, except at prices that are politically impossible (or are deniable promises about future plans).
    • Second, because with these launch costs, the payloads must be enormously more reliable and compact than commercial off-the-shelf hardware — and therefore enormously expensive in their own right.

I believe most people have great sympathy and enthusiasm for humans-in-space. They really “get” the big picture. Unfortunately, their sympathy and enthusiasm has been abused.

Humankind’s presence in space is essential to long-term human survival.

That is why I urge that we reject any major humans-in-space initiative that does not have the prerequisite goal of much cheaper (at least by a factor of ten) access to space.

We at Lifeboat Foundation wholeheartedly agree. A self-sustaining space station, which could weigh thousands or even millions of tons (the International Space Station weighs 235 tons), must be built out of components either harvested in space or launched for costs less than an order of magnitude than the current costs. We’re coming to a point in history where these expensive launches are just a waste. Why invest billions in going to Mars when we can’t even get out of our own atmosphere for anything less than millions of dollars? We have to put investment towards better approaches to launch. Superconducting maglev or mass driver approaches likely hold the key.

Using maps of population density, the researchers charted the places likely to suffer the most casualties from asteroids. As might be expected, countries with large coastal populations turned out to be most vulnerable, with China, Indonesia, India, Japan and the US in the top five spots.

The team focused on smaller asteroids because they hit the Earth more frequently. An asteroid a few hundred metres across hits the planet about once every 10,000 years, on average, while those larger than 1 kilometre hit only every 100,000 years or so. Small asteroids are also harder to spot. They considered a range of impact energies corresponding to asteroids between 100 and 500 metres across, striking with typical solar system speeds of about 20,000 kilometres per second.


Simulations show the asteroid impact locations that would produce the most casualties in red. The Pacific coast of Asia is a particularly deadly place for an asteroid to strike because of tsunamis, while a direct strike on some densely populated inland areas could also cause a heavy toll (Illustration: Nick Bailey et al/University of Southampton)

The US faced the worst potential economic losses, since it has a lot of infrastructure on coastlines facing two different oceans. China was second, followed by Sweden, Canada, and Japan.

The Lifeboat asteroid shield project helps to address these risks and Tsunami warning and response systems would also help mitigate loss of life from ocean impacts.

From Physorg.com:

New Mexico’s governor Bill Richardson worked with the southwest desert state’s legislature to secure 33 million dollars for the final design of “Spaceport America,” the world’s first commercial spaceport.

Now the voters in the Dona Ana County municipality where the project is to be located will weigh in, in a referendum scheduled for April 3 on a new sales tax to fund the project.

If Spaceport America meets with voter approval, a maiden space voyage is expected in two to three years. If passed, the new tax would add 25 cents to a 100-dollar purchase, bringing in about 6.5 million dollars per year.

The project cleared a first hurdle earlier this month, garnering broad support from local lawmakers.

“The legislature gave its unanimous support to move forward aggressively with the spaceport,” said Rick Homans, chairman of the New Mexico Spaceport Authority, in a statement.

“They have given us the green light to put all systems ‘Go,’” he said.

New Mexico officials acknowledge being swept up in something of a space race in their bid to be the world’s first functioning spaceport.

Race away! It’s about time that the action in the private spaceflight sector is really picking up. The more players, the more competition, the more progress! Although launch costs are about $5,000/lb. at present, efforts like this will push costs down to $1,000/lb., and then to $500/lb. and below, far sooner than many people think!

NASA estimates the cost to find at least 90 percent of the 20,000 potentially hazardous asteroids and comets by 2020 would be about $1 billion, according to a report NASA will release later this week. It would cost $300 million if a asteroid locating telescope was piggybacked on another vehicle. The report was previewed Monday at a Planetary Defense Conference in Washington.

The agency is already tracking bigger objects, at least 3,300 feet in diameter, that could wipe out most life on Earth, much like what is theorized to have happened to dinosaurs 65 million years ago. But even that search, which has spotted 769 asteroids and comets — none of which is on course to hit Earth — is behind schedule. It’s supposed to be complete by the end of next year.

A cheaper option would be to simply piggyback on other agencies’ telescopes, a cost of about $300 million, also rejected, Johnson said.

“The decision of the agency is we just can’t do anything about it right now,” he added.

Earth got a scare in 2004, when initial readings suggested an 885-foot asteroid called 99942 Apophis seemed to have a chance of hitting Earth in 2029. But more observations showed that wouldn’t happen. Scientists say there is a 1-in-45,000 chance that it could hit in 2036.

They think it would mostly likely strike the Pacific Ocean, which would cause a tsunami on the U.S. West Coast the size of the devastating 2004 Indian Ocean wave.

John Logsdon, space policy director at George Washington University, said a stepped-up search for such asteroids is needed.

“You can’t deflect them if you can’t find them,” Logsdon said. “And we can’t find things that can cause massive damage.”

Lifeboat has an asteroid shield project

From Physorg.com:

With a typical launch cost for a spaceship around $20 million, it’s difficult to practically conceive of a space industry beyond federally funded agencies. Nevertheless, many people believe that expanding space travel—whether for research purposes, entertainment, or even colonization—is not impractical. Bridging the economic hurdle may be technologies such as the maglev launch assist. According to an analysis, the cost of launching payloads into the low earth orbit with maglev may be achieved with only hundreds of dollars per pound (John Olds and Peter Bellini).

Most recently, researchers in a group including Wenjiang Yang and his colleagues from the Beijing University of Aeronautics and Astronautics and the Chinese Academy of Sciences have investigated the possibility of the “Maglifter,” a maglev launch assist vehicle originally proposed in the 1980s. In this system, a spaceship would be magnetically levitated over a track and accelerated up an incline, lifting off when it reaches a velocity of 1,000 km/hr (620 miles/hr). The main cost-saving areas would come from reduced fuel consumption and the reduced mass of the spaceship.

“Magnetic levitation is a promising technology for future space transportation,” Yang told PhysOrg.com. “The most expensive part of space missions to low-Earth orbit is the first few seconds—getting off the ground.”

Obviously, cost-to-orbit is highly relevant to Lifeboat’s push to build a space ark. Some might find it hard to imagine how a non-governmental organization has even a chance of building a space station in the foreseeable future, but that’s because cost-to-orbit has historically been over $10,000 per pound. With new launch technologies like maglev-assist, the cost could come down to hundreds per pound or below. Dropping costs in launch technologies are something that we can expect to accelerate once it really gets started — especially with the growing interest in private space travel.

Take a look at the Lifeboat Foundation EM Launch Competition!

“The importance of the space sector can be emphasized by the number of spacecrafts launched. In the period from 1957 till 2005, 6376 spacecraft have been launched at an average of 133 per year. The has been a decrease in the number of spacecrafts launched in the recent years with 78 launched in 2005. Of the 6378 launches, 56.8% were military spacecrafts and 43.2 were civilian. 245 manned missions have been launched in this period. 1674 communication or weather satellites were also launched. The remaining spacecraft launches has been exploration missions.”

Read the entire report here (requires free registration)

Graduate student (University of Alabama Huntsville) Blake Anderton wrote his master’s thesis on “Application of Mode-locked lasers to asteroid characterization and mitigation.” Undergraduate Gordon Aiken won a prize at a recent student conference for his poster and presentation “Space positioned LIDAR system for characterization and mitigation of Near Earth Objects.” And members of the group are building a laser system “that is the grandfather of the laser that will push the asteroids,” Fork said.

Anderton’s mode locked lasers could characterize asteroids up to 1 AU away (1.5 × 10 to the 11 meters). Arecibo and other radar observatories can only detect objects up to 0.1 AU away, so in theory a laser would represent a vast improvement over radar.

A one page powerpoint describes their asteroid detection and deflection approach About 12 of the 1AU detection volumes (around the sun in the asteroid belt) would be needed to cover the main areas for near earth asteroids.

40KW femtosecond lasers could deflect an asteroid the size of Apophis (320meters, would hit with 880 megaton force) given one year of illumination and an early start in the trajectory.

Asteroid shields are a project of the Lifeboat Foundation

There are 67 kilowatt solid state lasers and modular laser systems & mirrors for reflecting lasers to achieve more laser power from smaller modules