$1,440 already pledged for this new endeavor on Space Solar Power:
http://www.kickstarter.com/projects/450844280/space-solar-power-and-the-sps-alpha-conceptUnless mankind leaves the Earth, it will surely die there. This blog is dedicated to exploring the manifest destiny of mankind to fill all creation with life and intelligence.
25 May 2012
Building Space Solar Power Satellites using Lunar Materials and In-Space Habitats
http://www.nss.org/settlement/journal/NSSJOURNAL_AnalysisOfONeill-GlaserModel_2011.pdf
If the 1 billion people were separated into 200 O’Neill habitats, each would house 5 million people, which is the lower population density (O'Neill, 1974) for the original double cylindrical habitat design. This migration could be accomplished in about 35 years, be completely financed by profits from SPS while stabilizing Earth’s global carbon emissions. The probability of human self-extinction during the natural life span of a child born today would decrease from some number uncomfortably close to 1 to a probability less then 1 in ten million.
If human population of 1 billion, all with habitat destroying technology, are dispersed in 50 or less habitats self-extinction within a decade is highly probable. However, with just 160 habitats the chances of self-extinction per year decrease to about one in a million.
Since the mid 20th century we had the technological power to destroy our species and our home planet. This technological power and its associated risks continue to grow with time at an exponential rate. When the human propensity for self destruction and the growth of the availability of technologies of mass destruction are considered, our self-extinction probability can be expected to approach 1 well before the end of this century.
If, on the other hand, a few hundred artificial worlds (as advocated by O'Neill) are placed in the solar system with enough space between them that if one self destructs its neighbor would not be directly affected then the chances of human self-extinction would fall to about 1 chance in 1 million per year.
The results are quite dramatic. While the ground based approach does not appear to be financially practical, the space based approach is financially compelling, promising extraordinary profit if implemented.
The world electricity consumption was about 1966 GW in 2005 and it is projected to be about 4,000 GW by the year 2036, which would be about year 27 of these analyses. Figure 5 gives the economics of the space derived (O’Neill – Glaser) SPS construction model for meeting world electrical power growth requirements and that for stabilization of CO2 emissions. Figure 7 gives the corresponding SPS power delivered to Earth. The “electricity” plan will create 970 GW by year 27, which is 24 percent of the world electricity demand. The higher demand plan will create 8660 GW by year 27, which meets the requirements of Garret’s thermal dynamic global warming model (Garrett, 20009) by replacing 2.1% percent of the total energy consumed each year by non-carbon-emitting sources in order to stabilize world CO2 emissions.From comparison of the curves in Figure 6 it is apparent that the economics of space derived SPS for the higher demand level needed to stabilize global CO2 are even more favorable than for the new electrical demand model. This occurs because after the space infrastructure is in place, there is a high profit margin on SPS production. Ramping up to this higher production requires greater initial investment (about $800 billion at year 17) however program break even occurs 4 years sooner at, at year 20. The profit projected by program year 25 is over $8 trillion.
The space derived (optimized O’Neill – Glaser) model requires an investment of $300 Billion to build the infrastructure on the Moon and in space to allow utilization of lunar materials and space based labor. Once the infrastructure is in place, however, the SPS are constructed more than an order of magnitude cheaper than by Earth launch. These inexpensive SPS have a very large profit margin even when selling electricity below Earth market values. The peak investment of about $460 Billion is paid back at program year 24 and by program year 27 the project is projected to realize $600 Billion in profits.
As shown in Figure 8, the space derived SPS program is capable of financing in
the first 35 years 800 thousand people for the electricity scenario and 1.1 billion people in
space for the CO2 stabilization scenario. This includes construction of large vista O’Neill
habitats, transportation of the population from Earth to the space habitation, and the population’s
living expenses in space. Again 80% of the population is employed in building SPS or
habitation. After this space real estate focus the space population can be naturally deployed
to develop a solar system based economy.
The solar system economy would have little near term limits to growth since the carrying capacity of the asteroid belt alone utilizing O’Neill habitats is estimated to be 10-100 trillion people (Billingham et al, 1979).
If the 1 billion people were separated into 200 O’Neill habitats, each would house 5 million people, which is the lower population density (O'Neill, 1974) for the original double cylindrical habitat design. This migration could be accomplished in about 35 years, be completely financed by profits from SPS while stabilizing Earth’s global carbon emissions. The probability of human self-extinction during the natural life span of a child born today would decrease from some number uncomfortably close to 1 to a probability less then 1 in ten million.
If human population of 1 billion, all with habitat destroying technology, are dispersed in 50 or less habitats self-extinction within a decade is highly probable. However, with just 160 habitats the chances of self-extinction per year decrease to about one in a million.
Since the mid 20th century we had the technological power to destroy our species and our home planet. This technological power and its associated risks continue to grow with time at an exponential rate. When the human propensity for self destruction and the growth of the availability of technologies of mass destruction are considered, our self-extinction probability can be expected to approach 1 well before the end of this century.
If, on the other hand, a few hundred artificial worlds (as advocated by O'Neill) are placed in the solar system with enough space between them that if one self destructs its neighbor would not be directly affected then the chances of human self-extinction would fall to about 1 chance in 1 million per year.
The results are quite dramatic. While the ground based approach does not appear to be financially practical, the space based approach is financially compelling, promising extraordinary profit if implemented.
The world electricity consumption was about 1966 GW in 2005 and it is projected to be about 4,000 GW by the year 2036, which would be about year 27 of these analyses. Figure 5 gives the economics of the space derived (O’Neill – Glaser) SPS construction model for meeting world electrical power growth requirements and that for stabilization of CO2 emissions. Figure 7 gives the corresponding SPS power delivered to Earth. The “electricity” plan will create 970 GW by year 27, which is 24 percent of the world electricity demand. The higher demand plan will create 8660 GW by year 27, which meets the requirements of Garret’s thermal dynamic global warming model (Garrett, 20009) by replacing 2.1% percent of the total energy consumed each year by non-carbon-emitting sources in order to stabilize world CO2 emissions.From comparison of the curves in Figure 6 it is apparent that the economics of space derived SPS for the higher demand level needed to stabilize global CO2 are even more favorable than for the new electrical demand model. This occurs because after the space infrastructure is in place, there is a high profit margin on SPS production. Ramping up to this higher production requires greater initial investment (about $800 billion at year 17) however program break even occurs 4 years sooner at, at year 20. The profit projected by program year 25 is over $8 trillion.
The space derived (optimized O’Neill – Glaser) model requires an investment of $300 Billion to build the infrastructure on the Moon and in space to allow utilization of lunar materials and space based labor. Once the infrastructure is in place, however, the SPS are constructed more than an order of magnitude cheaper than by Earth launch. These inexpensive SPS have a very large profit margin even when selling electricity below Earth market values. The peak investment of about $460 Billion is paid back at program year 24 and by program year 27 the project is projected to realize $600 Billion in profits.
As shown in Figure 8, the space derived SPS program is capable of financing in
the first 35 years 800 thousand people for the electricity scenario and 1.1 billion people in
space for the CO2 stabilization scenario. This includes construction of large vista O’Neill
habitats, transportation of the population from Earth to the space habitation, and the population’s
living expenses in space. Again 80% of the population is employed in building SPS or
habitation. After this space real estate focus the space population can be naturally deployed
to develop a solar system based economy.
The solar system economy would have little near term limits to growth since the carrying capacity of the asteroid belt alone utilizing O’Neill habitats is estimated to be 10-100 trillion people (Billingham et al, 1979).
21 May 2012
The Inadequacy of Current Space Law to Protect and Encourage Investment
From: http://www.dailymail.co.uk/sciencetech/article-2137806/Legal-expert-says-James-Camerons-multi-billion-space-mining-venture-hit-lawsuits.html
Not clear who OWNS asteroids
Under 1967 Space Treaty, space is a 'global commons'
University of Nebraska expert says venture may face serious legal problems
New venture backed by Google chiefs and Avatar's James Cameron
100-foot asteroid can contain $50 BILLION of platinum
Spacecraft could mine near-earth rocks for platinum
Plan would add 'trillions' to global GDP
Planetary Resources, the Seattle-based 'asteroid mining' company set up by Google chiefs Larry Page and Eric Schmidt and filmmaker James Cameron could run into legal problems.
It's not clear who actually OWNS asteroids.
Frans von der Dunk, professor of space law at the University of Nebraska-Lincoln said that existing laws applying to space meant there was no certainty that ‘asteroid mining’ was legal.
It’s also not certain, von der Dunk said, about who owns rocks in space, which is, according to the 1967 Global Space Treaty, ‘a global commons’.
The plan to bring back trillions of pounds worth of platinum from space rocks might not be as simple as some have hoped.
‘Neither the pubic interests, ranging from security, safety and the environment to protecting Neil Armstrong’s footsteps, nor the interests of the company in securing its investments are properly protected,’ said von der Dunk.
The Nebraska professor said that the venture would be open to legal suits - and that it would also have no defence against rivals.
‘Consequently, there is no legal certainty that those activities would not become seriously challenged.’
‘This prompts several questions: What rights of protection would the mining company have against others wishing to ‘intrude,’ given that a global commons is in a principled fashion open to everyone?’ Von der Dunk said.
‘And, who is going to be held liable – and to what extent – when mining activities cause damage to other space activities or are harmed by them?’
But wealth beyond the dreams of avarice may NOT be immediately forthcoming.
Several scientists not involved in the project said they were simultaneously thrilled and wary, calling the plan daring, difficult - and pricey.
They don't see how it could be cost-effective, even with platinum and gold worth nearly $1,600 an ounce.
An upcoming NASA mission to return just 2 ounces (60 grams) of an asteroid to Earth will cost about $1 billion.
Scientists question how the company can reduce costs to the point where 'space mining' will be profitable.
Planetary Resources, based in Bellevue, Washington, initially will focus on developing and selling extremely low-cost robotic spacecraft for surveying missions, the company announced this week.
A demonstration mission in orbit around Earth is expected to be launched within two years, said company co-founders Peter Diamandis and Eric Anderson.
Anderson acknowledged the many potential pitfalls.
'There will be times when we fail,' he said. 'There will be times when we have to pick up the pieces and try again.'
Within five to 10 years, however, the company expects to progress from selling observation platforms in orbit around Earth to prospecting services.
It plans to tap some of the thousands of asteroids that pass relatively close to Earth and extract their raw materials.
A 98-foot asteroid can hold as much as $50 billion worth of platinum (£31 billion) at today's prices, said a company spokesperson.
Not all missions would return precious metals and minerals to Earth. In addition to mining for platinum and other precious metals, the company plans to tap asteroids' water to supply orbiting fuel depots, which could be used by NASA and others for robotic and human space missions.
'We have a long view. We're not expecting this company to be an overnight financial home run. This is going to take time,' Anderson said in an interview with Reuters.
The real payoff, which is decades away, will come from mining asteroids for platinum group metals and rare minerals.
'If you look back historically at what has caused humanity to make its largest investments in exploration and in transportation, it has been going after resources, whether it's the Europeans going after the spice routes or the American settlers looking toward the west for gold, oil, timber or land,; Diamandis said.
'Those precious resources caused people to make huge investments in ships and railroads and pipelines. Looking to space, everything we hold of value on Earth - metals, minerals, energy, real estate, water - is in near-infinite quantities in space.
'The opportunity exists to create a company whose mission is to be able to go and basically identify and access some of those resources and ultimately figure out how to make them available where they are needed,' he said.
Diamandis and Anderson declined to discuss how much money has been raised for their venture so far.
In addition to Google billionaires Page and Schmidt and filmmaker Cameron, Planetary Resources investors include former Microsoft chief software architect Charles Simonyi, a two-time visitor to the International Space Station, Google founding director K. Ram Shriram and Ross Perot Jr.
Planetary Resources also declined to discuss specifics about how and when asteroid mining would begin.
The shortage of sources for raw materials on the planet has caused global inflation to spike in recent years causing tensions to rise between nations, experts have said.
The company's first step is to develop technologies to cut the cost of deep-space robotic probes to one-tenth to one-hundredth the cost of current space missions, which run hundreds of millions of dollars, Diamandis said.
Among the targeted technologies is optical laser communications, which would eliminate the need for large radio antennas aboard spacecraft.
Space entrepreneurs Peter Diamandis and Eric Anderson are just two of the names behind Planetary Resource. In a press release, the company announced its intentions to create 'a new industry in space and a new definition of natural resources'.
Diamandis and Anderson - both known for their aspirations for commercial space exploration - will host the launch event along with two former NASA officials.
A driving force behind the Ansari X-Prize competition to spur on non-goverment space flight, Diamandis has made no secret of his goal to one day become an asteroid miner.
In an interview earlier this year with Forbes magazine, he said: 'The earth is a crumb in a supermarket of resources.
'Now we finally have the technology to extract resources outside earth for the benefit of humanity without having to rape and pillage our planet.'
Hollywood film maker James Cameron is no stranger to daring exploration.
Just last month the director of Titanic and Avatar became the first solo diver to reach the bottom of the Challenger Deep - the deepest point on Earth.
It might seem like a radical concept, but scientists have been toying with the idea of mining asteroids for their natural resources for longer than the space program has been running.
Experts believe it is only now that we have the technology and ability to discover and characterise a sufficient number of small near-Earth asteroids (NEA).
The mining could yield a large amount of water - frozen inside the asteroids - oxygen and metals which could not only be brought back to Earth but could help further space exploration by allowing humans to fuel spacecraft and build space stations.
Nasa believes capturing placing an NEA in lunar orbit could provide a unique, meaningful and easy-to-reach destination for exploration by astronaut crews in the next decade.
It is only now that the sufficiently-powerful electric propulsion systems necessary to transport a captured NEA are becoming available.
Mining asteroids could take several forms. This includes sending humans in a spacecraft to an asteroid to explore and mine it.
Another possible scenario could involve launching a robotic spacecraft to either to mine an asteroid directly or transport it closer to Earth so it could be reached by humans more easily.
Extracting raw materials, such as iron and nickel, from the space rocks is a possibility that has been discussed for decades.
However, the obstacles for such a mission has always been the cost, sufficient scientific expertise and technical prowess.
It could cost tens of billions of dollars - and could take well over a decade - for astronauts to successfully land on an asteroid, NASA experts have said in the past.
Source: The Institute for Space Studies
Read more: http://www.dailymail.co.uk/sciencetech/article-2137806/Legal-expert-says-James-Camerons-multi-billion-space-mining-venture-hit-lawsuits.html#ixzz1vWHEq6Hf
Hang on, do you actually OWN all those asteroids full of platinum? Legal expert says James Cameron's multi-billion space mining venture may be hit with lawsuits
By ROB WAUGH All By This Author - 01/05/2012 14:46:18
Frans von der Dunk, professor of space law at the University of Nebraska-Lincoln said that existing laws applying to space meant there was no certainty that ‘asteroid mining’ was legal.
It's not clear who actually OWNS asteroids.
Frans von der Dunk, professor of space law at the University of Nebraska-Lincoln said that existing laws applying to space meant there was no certainty that ‘asteroid mining’ was legal.
It’s also not certain, von der Dunk said, about who owns rocks in space, which is, according to the 1967 Global Space Treaty, ‘a global commons’.
We're hiring! Two of Google's bosses and other technology luminaries in Seattle, USA, launched a company called Planetary Resources, aimed at developing robotic spaceships to mine near-Earth asteroids
James Cameron gives two thumbs-up as he emerges from the Deepsea Challenger: Planetary Resources, the Seattle-based 'asteroid mining' company set up by Google chiefs and Cameron could run into legal problems
The plan to bring back trillions of pounds worth of platinum from space rocks might not be as simple as some have hoped.
‘Neither the pubic interests, ranging from security, safety and the environment to protecting Neil Armstrong’s footsteps, nor the interests of the company in securing its investments are properly protected,’ said von der Dunk.
The Nebraska professor said that the venture would be open to legal suits - and that it would also have no defence against rivals.
‘Consequently, there is no legal certainty that those activities would not become seriously challenged.’
‘This prompts several questions: What rights of protection would the mining company have against others wishing to ‘intrude,’ given that a global commons is in a principled fashion open to everyone?’ Von der Dunk said.
‘And, who is going to be held liable – and to what extent – when mining activities cause damage to other space activities or are harmed by them?’
Miners wanted: A computer generated image of swarms of low-cost robotic spacecraft that will enable extraction of resources from Near-Earth asteroids
The new gold rush? Clint Eastwood, Lee Marvin and Jean Seberg in Gold Rush-themed musical 'Paint Your Wagon'
Several scientists not involved in the project said they were simultaneously thrilled and wary, calling the plan daring, difficult - and pricey.
They don't see how it could be cost-effective, even with platinum and gold worth nearly $1,600 an ounce.
An upcoming NASA mission to return just 2 ounces (60 grams) of an asteroid to Earth will cost about $1 billion.
Scientists question how the company can reduce costs to the point where 'space mining' will be profitable.
Planetary Resources, based in Bellevue, Washington, initially will focus on developing and selling extremely low-cost robotic spacecraft for surveying missions, the company announced this week.
A demonstration mission in orbit around Earth is expected to be launched within two years, said company co-founders Peter Diamandis and Eric Anderson.
Anderson acknowledged the many potential pitfalls.
'There will be times when we fail,' he said. 'There will be times when we have to pick up the pieces and try again.'
Cosmic quarry: A team of scientists have unveiled plans to mine asteroids for their raw materials
Mars Rover Curiosity - currently on its way to the Red Planet: The new company aims to reduce the cost of hardware for space exploration by a factor of 100
It plans to tap some of the thousands of asteroids that pass relatively close to Earth and extract their raw materials.
A 98-foot asteroid can hold as much as $50 billion worth of platinum (£31 billion) at today's prices, said a company spokesperson.
Not all missions would return precious metals and minerals to Earth. In addition to mining for platinum and other precious metals, the company plans to tap asteroids' water to supply orbiting fuel depots, which could be used by NASA and others for robotic and human space missions.
'We have a long view. We're not expecting this company to be an overnight financial home run. This is going to take time,' Anderson said in an interview with Reuters.
The real payoff, which is decades away, will come from mining asteroids for platinum group metals and rare minerals.
Nasa has already successsfully landed a probe on an asteroid, Eros, 196 million miles from Earth
'Those precious resources caused people to make huge investments in ships and railroads and pipelines. Looking to space, everything we hold of value on Earth - metals, minerals, energy, real estate, water - is in near-infinite quantities in space.
'The opportunity exists to create a company whose mission is to be able to go and basically identify and access some of those resources and ultimately figure out how to make them available where they are needed,' he said.
Diamandis and Anderson declined to discuss how much money has been raised for their venture so far.
In addition to Google billionaires Page and Schmidt and filmmaker Cameron, Planetary Resources investors include former Microsoft chief software architect Charles Simonyi, a two-time visitor to the International Space Station, Google founding director K. Ram Shriram and Ross Perot Jr.
Planetary Resources also declined to discuss specifics about how and when asteroid mining would begin.
NASA's infrared sky-scans track space objects such as asteroids. A recent scan with the NeoWISE instruments found that there were 19,000 'mid-sized' asteroids within 120 million miles of Earth
Backing: Film maker and explorer James Cameron (left) is supporting the project, as is billionaire Charles Simonyi (right)
Untapped resource: NASA scientists say the high concentration of raw materials found in asteroids could supply Earth with vital stockpiles of natural resources
Space man: Entrepreneur Peter Diamandis
The company's first step is to develop technologies to cut the cost of deep-space robotic probes to one-tenth to one-hundredth the cost of current space missions, which run hundreds of millions of dollars, Diamandis said.
Among the targeted technologies is optical laser communications, which would eliminate the need for large radio antennas aboard spacecraft.
Space entrepreneurs Peter Diamandis and Eric Anderson are just two of the names behind Planetary Resource. In a press release, the company announced its intentions to create 'a new industry in space and a new definition of natural resources'.
Diamandis and Anderson - both known for their aspirations for commercial space exploration - will host the launch event along with two former NASA officials.
A driving force behind the Ansari X-Prize competition to spur on non-goverment space flight, Diamandis has made no secret of his goal to one day become an asteroid miner.
In an interview earlier this year with Forbes magazine, he said: 'The earth is a crumb in a supermarket of resources.
'Now we finally have the technology to extract resources outside earth for the benefit of humanity without having to rape and pillage our planet.'
Hollywood film maker James Cameron is no stranger to daring exploration.
Just last month the director of Titanic and Avatar became the first solo diver to reach the bottom of the Challenger Deep - the deepest point on Earth.
Radical concept, but old idea: Experts believe it is only now that we have the ability to discover and characterise a sufficient number of small near-Earth asteroids
Straight out of a sci-fi film: A scene from the movie Armageddon, where Bruce Willis's character is sent into space to mine an asteroid before it hits the Earth
COSMIC QUARRIES: AN IDEA AS OLD AS THE SPACE PROGRAM
Experts believe it is only now that we have the technology and ability to discover and characterise a sufficient number of small near-Earth asteroids (NEA).
The mining could yield a large amount of water - frozen inside the asteroids - oxygen and metals which could not only be brought back to Earth but could help further space exploration by allowing humans to fuel spacecraft and build space stations.
Nasa believes capturing placing an NEA in lunar orbit could provide a unique, meaningful and easy-to-reach destination for exploration by astronaut crews in the next decade.
It is only now that the sufficiently-powerful electric propulsion systems necessary to transport a captured NEA are becoming available.
Mining asteroids could take several forms. This includes sending humans in a spacecraft to an asteroid to explore and mine it.
Another possible scenario could involve launching a robotic spacecraft to either to mine an asteroid directly or transport it closer to Earth so it could be reached by humans more easily.
Extracting raw materials, such as iron and nickel, from the space rocks is a possibility that has been discussed for decades.
However, the obstacles for such a mission has always been the cost, sufficient scientific expertise and technical prowess.
It could cost tens of billions of dollars - and could take well over a decade - for astronauts to successfully land on an asteroid, NASA experts have said in the past.
Source: The Institute for Space Studies
Read more: http://www.dailymail.co.uk/sciencetech/article-2137806/Legal-expert-says-James-Camerons-multi-billion-space-mining-venture-hit-lawsuits.html#ixzz1vWHEq6Hf
The galactic shredder: Nasa captures huge black hole pulling star to pieces after red giant 'wanders too close'
By ROB WAUGH All By This Author - 03/05/2012 12:52:17
A star that wandered too close to the centre of a galaxy 2.7 billion light years away was pulled in by the enormous gravity of the black hole - and shredded.
Nasa probe flies past Saturn's icy moon Enceladus just 46 miles up - and captures mystery 'jets' of ice which may harbour life
By ROB WAUGH All By This Author - 03/05/2012 16:41:10
A hair-raisingly close fly-by by Nasa's Cassini Probe aims to learn more about what lurks beneath the icy moon Enceladus's surface - and what exactly lurks in the 'geysers' of ice it spews into space.
This is the way the world ends: Planets turned to dust devoured by a white dwarf star offer a glimpse of our own apocalypse
By ROB WAUGH All By This Author - 04/05/2012 12:06:37
University of Warwick researchers found four white dwarves surrounded by the dust of shattered 'Earths' White dwarfs are the final stage of life of stars like our Sun - once the furnace inside a star 'burns out'.
Zayed Future Energy Prize
http://www.zayedfutureenergyprize.com/en/
A new prize for global energy...will Zayed discover SBSP
A new prize for global energy...will Zayed discover SBSP
Space Solar Swarm!
From: http://www.dailymail.co.uk/sciencetech/article-2145149/Solar-satellites-offer-hope-green-energy-actually-WORK.html?ito=feeds-newsxml
By Rob Waugh
PUBLISHED: 04:01 EST, 16 May 2012 | UPDATED: 04:23 EST, 16 May 2012
On Earth, solar power has had a slow start, thanks to high prices and inefficient panels - but the first tests on 'solar satellites' offer hope of 'green energy' that actually works.
Researchers at Stratchclyde University have already tested equipment in space, a first step for solar panels to collect energy and transfer it back to earth through microwaves or lasers.
The researchers aim to produce a 'swarm' of satellites that could one day power whole cities.
Initially the tiny satellites wouldn't replace ordinary power grids - instead, they could swiftly resupply power to disaster areas or outlying districts that are difficult to reach.
A 'receiver' on Earth would turn the precisely targeted microwave or laser beams into usable electricity.
The idea of solar panels in space has been much discussed - but the new research proves that at least a small-scale version IS possible.
Dr Massimiliano Vasile, of the University of Strathclyde’s Department of Mechanical and Aerospace Engineering, who is leading the space based solar power research, said: ‘Space provides a fantastic source for collecting solar power and we have the advantage of being able to gather it regardless of the time of the day or indeed the weather conditions.‘In areas like the Sahara desert where quality solar power can be captured, it becomes very difficult to transport this energy to areas where it can be used.
'However, our research is focusing on how we can remove this obstacle and use space based solar power to target difficult to reach areas.
'This would provide a reliable, quality source of energy and would remove the need for storing energy coming from renewable sources on ground as it would provide a constant delivery of solar energy.
‘Initially, smaller satellites will be able to generate enough energy for a small village but we have the aim, and indeed the technology available, to one day put a large enough structure in space that could gather energy that would be capable of powering a large city.’
Last month, a team of science and engineering students at Strathclyde developed an innovative ‘space web’ experiment which was carried on a rocket from the Arctic Circle to the edge of space.
The experiment, known as Suaineadh – or ‘twisting’ in Scots Gaelic, was an important step forward in space construction design and demonstrated that larger structures could be built on top of a light-weight spinning web, paving the way for the next stage in the solar power project.
Dr Vasile added: ‘The success of Suaineadh allows us to move forward with the next stage of our project which involves looking at the reflectors needed to collect the solar power.
‘The current project, called SAM (Self-inflating Adaptable Membrane) will test the deployment of an ultra light cellular structure that can change shape once deployed. The structure is made of cells that are self-inflating in vacuum and can change their volume independently through nanopumps.
‘The structure replicates the natural cellular structure that exists in all living things. The independent control of the cells would allow us to morph the structure into a solar concentrator to collect the sunlight and project it on solar arrays. The same structure can be used to build large space systems by assembling thousands of small individual units.’
The project is part of a NASA Institute for Advanced Concepts (NIAC) study led by Dr John Mankins of Artemis Innovation. The University of Strathclyde represents the European section of an international consortium involving American researchers, and a Japanese team, led by Professor Nobuyuki Kaya of the University of Kobe, a world leader in wireless power transmission.
The NIAC study is demonstrating a new conceptual design for large scale solar power satellites. The role of the team at the University of Strathclyde is to develop innovative solutions for the structural elements and new solutions for orbit and orbit control.
Read more: http://www.dailymail.co.uk/sciencetech/article-2145149/Solar-satellites-offer-hope-green-energy-actually-WORK.html#ixzz1vVpIXEQc
Beams' from space that could power cities: First tests on solar satellites offer hope of green energy that might actually WORK
Floating solar panels 'beam' energy to Earth using lasers or microwaves
Equipment tested in space to deploy 'swarm' of solar panels
Initially will supply power to disaster areas or outlying regions
Eventually 'swarm' of tiny satellites could power cities
PUBLISHED: 04:01 EST, 16 May 2012 | UPDATED: 04:23 EST, 16 May 2012
On Earth, solar power has had a slow start, thanks to high prices and inefficient panels - but the first tests on 'solar satellites' offer hope of 'green energy' that actually works.
Researchers at Stratchclyde University have already tested equipment in space, a first step for solar panels to collect energy and transfer it back to earth through microwaves or lasers.
The researchers aim to produce a 'swarm' of satellites that could one day power whole cities.
Initially, the tiny satellites wouldn't replace ordinary power grids - instead, they could swiftly resupply power to disaster areas or outlying districts that are difficult to reach
Solar satellite: The researchers aim to produce a 'swarm' of satellites that could one day power whole cities
Dr Massimiliano Vasile, of Strathclyde¿s Department of Mechanical and Aerospace Engineering, is leading the research
A 'receiver' on Earth would turn the precisely targeted microwave or laser beams into usable electricity.
The idea of solar panels in space has been much discussed - but the new research proves that at least a small-scale version IS possible.
Dr Massimiliano Vasile, of the University of Strathclyde’s Department of Mechanical and Aerospace Engineering, who is leading the space based solar power research, said: ‘Space provides a fantastic source for collecting solar power and we have the advantage of being able to gather it regardless of the time of the day or indeed the weather conditions.‘In areas like the Sahara desert where quality solar power can be captured, it becomes very difficult to transport this energy to areas where it can be used.
'However, our research is focusing on how we can remove this obstacle and use space based solar power to target difficult to reach areas.
‘By using either microwaves or lasers we would be able to beam the energy back down to earth, directly to specific areas.
'This would provide a reliable, quality source of energy and would remove the need for storing energy coming from renewable sources on ground as it would provide a constant delivery of solar energy.
‘Initially, smaller satellites will be able to generate enough energy for a small village but we have the aim, and indeed the technology available, to one day put a large enough structure in space that could gather energy that would be capable of powering a large city.’
Last month, a team of science and engineering students at Strathclyde developed an innovative ‘space web’ experiment which was carried on a rocket from the Arctic Circle to the edge of space.
The researchers already deployed a network of satellites which could be used to 'beam' power back to Earth
Dr Vasile added: ‘The success of Suaineadh allows us to move forward with the next stage of our project which involves looking at the reflectors needed to collect the solar power.
‘The current project, called SAM (Self-inflating Adaptable Membrane) will test the deployment of an ultra light cellular structure that can change shape once deployed. The structure is made of cells that are self-inflating in vacuum and can change their volume independently through nanopumps.
‘The structure replicates the natural cellular structure that exists in all living things. The independent control of the cells would allow us to morph the structure into a solar concentrator to collect the sunlight and project it on solar arrays. The same structure can be used to build large space systems by assembling thousands of small individual units.’
The project is part of a NASA Institute for Advanced Concepts (NIAC) study led by Dr John Mankins of Artemis Innovation. The University of Strathclyde represents the European section of an international consortium involving American researchers, and a Japanese team, led by Professor Nobuyuki Kaya of the University of Kobe, a world leader in wireless power transmission.
The NIAC study is demonstrating a new conceptual design for large scale solar power satellites. The role of the team at the University of Strathclyde is to develop innovative solutions for the structural elements and new solutions for orbit and orbit control.
Read more: http://www.dailymail.co.uk/sciencetech/article-2145149/Solar-satellites-offer-hope-green-energy-actually-WORK.html#ixzz1vVpIXEQc
NASA survey counts potentially hazardous asteroids
From: http://www.kurzweilai.net/nasa-survey-counts-potentially-hazardous-asteroids
NASA survey counts potentially hazardous asteroids
May 21, 2012
Wide-field Infrared Survey Explorer (WISE), which have led to the best assessment yet of our solar system’s population of potentially hazardous asteroids.
Potentially hazardous asteroids are a subset of the larger group of near-Earth asteroids. The PHAs have the closest orbits to Earth’s, coming within five million miles (about eight million kilometers), and they are big enough to survive passing through Earth’s atmosphere and cause damage on a regional, or greater, scale.
The new results come from the asteroid-hunting portion of the WISE mission, called NEOWISE. The project sampled 107 PHAs to make predictions about the entire population as a whole. Findings indicate there are roughly 4,700 PHAs, plus or minus 1,500, with diameters larger than 330 feet (about 100 meters). So far, an estimated 20 to 30 percent of these objects have been found.
While previous estimates of PHAs predicted similar numbers, they were rough approximations. NEOWISE has generated a more credible estimate of the objects’ total numbers and sizes. It suggests that about twice as many PHAs as previously thought are likely to reside in “lower-inclination” orbits, which are more aligned with the plane of Earth’s orbit.
In addition, these lower-inclination objects appear to be somewhat brighter and smaller than the other near-Earth asteroids that spend more time far away from Earth. A possible explanation is that many of the PHAs may have originated from a collision between two asteroids in the main belt lying between Mars and Jupiter. A larger body with a low-inclination orbit may have broken up in the main belt, causing some of the fragments to drift into orbits closer to Earth and eventually become PHAs.
Asteroids with lower-inclination orbits would be more likely to encounter Earth and would be easier to reach. The results therefore suggest more near-Earth objects might be available for future robotic or human missions.
“NASA’s NEOWISE project, which wasn’t originally planned as part of WISE, has turned out to be a huge bonus,” said Amy Mainzer, NEOWISE principal investigator, at NASA’s Jet Propulsion Laboratory in Pasadena, Calif. “Everything we can learn about these objects helps us understand their origins and fate. Our team was surprised to find the overabundance of low-inclination PHAs. Because they will tend to make more close approaches to Earth, these targets can provide the best opportunities for the next generation of human and robotic exploration.”
The discovery that many PHAs tend to be bright says something about their composition; they are more likely to be either stony, like granite, or metallic. This type of information is important in assessing the space rocks’ potential hazards to Earth. The composition of the bodies would affect how quickly they might burn up in our atmosphere if an encounter were to take place.
There are roughly 4,700 potentially hazardous asteroids (PHAs) with diameters larger than 330 feet (about 100 meters). So far, an estimated 20 to 30 percent of these objects have been found, according to observations from NASA’s Potentially hazardous asteroids are a subset of the larger group of near-Earth asteroids. The PHAs have the closest orbits to Earth’s, coming within five million miles (about eight million kilometers), and they are big enough to survive passing through Earth’s atmosphere and cause damage on a regional, or greater, scale.
The new results come from the asteroid-hunting portion of the WISE mission, called NEOWISE. The project sampled 107 PHAs to make predictions about the entire population as a whole. Findings indicate there are roughly 4,700 PHAs, plus or minus 1,500, with diameters larger than 330 feet (about 100 meters). So far, an estimated 20 to 30 percent of these objects have been found.
While previous estimates of PHAs predicted similar numbers, they were rough approximations. NEOWISE has generated a more credible estimate of the objects’ total numbers and sizes. It suggests that about twice as many PHAs as previously thought are likely to reside in “lower-inclination” orbits, which are more aligned with the plane of Earth’s orbit.
In addition, these lower-inclination objects appear to be somewhat brighter and smaller than the other near-Earth asteroids that spend more time far away from Earth. A possible explanation is that many of the PHAs may have originated from a collision between two asteroids in the main belt lying between Mars and Jupiter. A larger body with a low-inclination orbit may have broken up in the main belt, causing some of the fragments to drift into orbits closer to Earth and eventually become PHAs.
Asteroids with lower-inclination orbits would be more likely to encounter Earth and would be easier to reach. The results therefore suggest more near-Earth objects might be available for future robotic or human missions.
“NASA’s NEOWISE project, which wasn’t originally planned as part of WISE, has turned out to be a huge bonus,” said Amy Mainzer, NEOWISE principal investigator, at NASA’s Jet Propulsion Laboratory in Pasadena, Calif. “Everything we can learn about these objects helps us understand their origins and fate. Our team was surprised to find the overabundance of low-inclination PHAs. Because they will tend to make more close approaches to Earth, these targets can provide the best opportunities for the next generation of human and robotic exploration.”
The discovery that many PHAs tend to be bright says something about their composition; they are more likely to be either stony, like granite, or metallic. This type of information is important in assessing the space rocks’ potential hazards to Earth. The composition of the bodies would affect how quickly they might burn up in our atmosphere if an encounter were to take place.
100 Year Starship
18 May 2012
100-Year Starship: Mae Jemison reaches for the stars
Mae Jemison fulfilled a childhood dream to travel to space. Now she wants to take humanity to the stars.
The 100-Year Starship, funded by the Defense Advanced Research Projects Agency (Darpa), isn’t about building the Starship Enterprise, at least not yet. Rather, it’s about creating a nonprofit organization that can sustain efforts over the next century to enable interstellar travel. The Dorothy Jemison Foundation, headed by Mae Jemison, was selected earlier this year to lead the 100-Year Starship.
This week the foundation announced its plans for shooting for the stars. First on the agenda is a gathering of scientists and the public in Houston, Texas, to discuss ways to advance interstellar travel.
Jemison spoke exclusively with BBC Future to talk about how she plans to lead humanity on an interstellar journey.
Q: You have signed up for an ambitious project. Are you sure that in 100 years, we’ll be ready to launch a starship?
Let me put it this way: It should happen within the 100 years. But if we can figure out how to do it faster, in 20 to 30 years, I’m good, because that way I get to go. Why do I think the technology arc is sufficient? If you think about it, HG Wells wrote First Men in the Moon in 1901. Imagine how incredulous, fantastical that idea was in 1901. We didn’t have rockets, we didn’t have the materials, and we weren’t really flying. It was incredible. Less than 100 years later, we were on the moon. I know we will have the technological knowledge if we choose to pursue it.
Q: To get to the stars, you need to push technology forward. What do you think needs to be a priority?
We’re in the process of developing the research issues. The first one is energy. Even if you say, I’ll take a 1,000 years to get there, you still have to figure how to generate enough energy to power a vehicle for [that length of time]. You can’t do that necessarily with solar energy. If you say I want to do it in a human lifetime, then enormous amounts of energy also have to be created.
Q: Your first step towards the stars will happen in Houston this September. Can you tell us what to expect?
What we really want to do with the symposium is provide a place where folks who are deep into [interstellar travel], whether from the social sciences or plasma physics, can have technical discussions, as well as being able to engage the public writ large in advocacy, participation, and in understanding what’s going on.
Q: What comes after that?
The symposium is a very strong declaration of, “we’re here.” At the same time, we have been actually working on the overall program. What we see with the 100-Year Starship is that it’s really a multidimensional organization. By that I mean, it’s an organization that has at its core a nonprofit foundation. That nonprofit foundation is there to make sure we maintain its purpose. We have the capacity to spinoff for-profit organizations as well: companies, ventures, and partnerships based on things that come around opportunistically.
Part of the nonprofit organization is also a research institute called the The Way, aptly named because it’s going to have us figure out the way to get to the stars. It not something that assumes we’re going to do all the work. It’s an institute to push the technologies, and advocate for radical leaps forward in technology.
We are not saying our organization, is going to be the one that necessarily launches a mission to the stars in a next 100 years. We want to be the little piece that crystalizes out, the effort, the energy, and the capacity to make sure that the capabilities exist within in the next 100 years in case somebody wants to launch a mission.
Q: So, do you think it’ll a public or private organization that actually launches a starship in the next 100 years?
If we start with an assumption right now that that it has to be public, or it has to be private, we may miss something along the way. Our approach right now is to come with a clean slate and say: what are some of the issues that need to be addressed in order to make that happen? And what are some of the benefits that occur if we go to interstellar space?
Some of the ideas that came out from this blank slate include how would economies change? How do you develop an economy that is not directly connected back with the United States? We have the example of people talking about asteroid mining, and bringing it back to Earth. What’s the benefit of not bringing it back to Earth? What does that economy look like? This is re-envisioning fundamental things.
Q: Part of the role the foundation will be fundraising for space travel. What will be your message to organizations or people you’re trying to raise money from.
Our proposal was titled: “An Inclusive Audacious Journey Transforms Life Here on Earth & Beyond.” That title goes to the very heart of what we’re doing. The first term is inclusive. I think we all know that we would have a lunar base right now, 40 years after Apollo 11, if there had been a public commitment. The fact we don’t have a lunar base has nothing to do with the technology. It has to do with public commitment and societal support.
Why did we have this gung ho spirit for a while, but we were not able to sustain it? I think it’s because many people did not see themselves as beneficiaries of it. That doesn’t mean you get money directly from it. It means, could you participate, could your children participate? Not necessarily being on the vehicle, but how does it impact your world? How does it impact your imagination, your aspiration? We want to look at inclusion, not only in terms of who builds the vehicle, or who does the research, but also the gender, ethnicity, and cultural pieces. We also want to look across disciplines. Something like this requires inclusion of the behavioral sciences, economics, art, and entertainment.
Q: You mention there wasn’t support for a lunar base. How will you ensure there’s support for something as ambitious as a 100-Year Starship?
We’re inviting the public to take part. The public didn’t leave space, they were left out. Nasa and many space organizations tried to do things, such as with teachers and education, but it didn’t feel like it was a public program.
I think that people need an adrenalin rush. Folks need something aspirational, they need to do something that is hard. That’s what ignites the imagination. I grew up during the Apollo-era, in the 1960s. When I was a little girl: I thought when I had an opportunity to go into space, I thought I would at a minimum be working on Mars, or another large planet because we were doing all of these incredible things. But we stagnated, because we didn’t continue that push. We started to get a little bit timid. Timidity does not inspire bold acts.
Interstellar by 2112!
Mae Jemison and Team Establish 100 Year Starship With Goal to Make Interstellar Space Travel Reality by 2112
by admin
HOUSTON, TX, May 17 2012 — The Dorothy Jemison Foundation for Excellence has been selected by the Defense Advanced Research Projects Agency (DARPA) to receive seed funding to form 100 Year Starship(TM) (100YSS(TM)), an independent, non-governmental, long-term initiative which will ensure that the capabilities for human interstellar flight exist as soon as possible, and definitely within the next 100 years. The winning 100YSS proposal “An Inclusive, Audacious Journey Transforms Life Here on Earth and Beyond,” was created by Dorothy Jemison Foundation for Excellence with team members Icarus Interstellar and the Foundation for Enterprise Development.
Former NASA astronaut Dr. Mae Jemison will lead the global multi-partner organization. Dr. Jemison, the world’s first woman of color to travel in space (1992’s Space Shuttle Endeavour), brings to her leadership role her vast experience as an engineer, physician, professor, former Peace Corps medical officer, and entrepreneur. Known for achieving the improbable, Dr. Jemison also brings a spirit of audacity, innovation and inclusion to 100YSS.
“Yes, it can be done. Our current technology arc is sufficient,” says Dr. Jemison. “100 Year Starship is about building the tools we need to travel to another star system in the next hundred years. We’re embarking on a journey across time and space. If my language is dramatic, it is because this project is monumental. This is a global aspiration. And each step of the way, its progress will benefit life on earth. Our team is both invigorated and sobered by the confidence DARPA has in us to start an independent, private initiative to help make interstellar travel a reality.”
100 Year Starship will bring in experts from myriad fields to help achieve its goal – utilizing not only scientists, engineers, doctors, technologists, researchers, sociologists and computer experts, but also architects, writers, artists, entertainers, and leaders in government, business, economics, ethics and public policy. 100YSS will also collaborate with existing space exploration and advocacy efforts from both private enterprise and the government.
In its first year, 100YSS will seek investors, establish membership opportunities, encourage public participation in research projects, and develop the visions for interstellar exploration. A 100 Year Starship Public Symposium will be held in Houston September 13-16, 2012, inaugurating what will be an annual event open to scientific papers, engineering challenges, philosophical and socio-cultural considerations, economic incentives, application of space technologies to improve life on earth, imaginative exploration of the stumbling blocks and opportunities to the stars, and broad public involvement.
The 100 Year Starship also will include a scientific research institute, The Way whose major emphasis will be speculative, long-term science and technology.
Alongside the Dorothy Jemison Foundation for Excellence, a non-profit organization that promotes science, technology, engineering and mathematics (STEM) awareness and achievement, the principal 100 Year Starship team members are: Icarus Interstellar, a non-profit research and development organization dedicated to the research that will enable interstellar flight; and the Foundation for Enterprise Development centered on governance, innovation, entrepreneurship, technology and R&D based organizational planning, management, and strategic planning. The SETI Institute, a private, non-profit organization dedicated to astronomy, life sciences, education, and public outreach, will hold a permanent seat on the 100YSS Advisory Council.
To sign up for e-mail alerts from 100 Year Starship or learn more about the 100YSS Public Symposium visit www.100YSS.org. Follow 100 Year Starship on Twitter (@100YSS). Contact 100 Year Starship at info@100YSS.org.
The Daedalus Starship. Designed by members of the British Interplanetary Society
in the 1970s – an inspiration for researchers of today. Image courtesy Adrian Mann.
Former NASA astronaut Dr. Mae Jemison will lead the global multi-partner organization. Dr. Jemison, the world’s first woman of color to travel in space (1992’s Space Shuttle Endeavour), brings to her leadership role her vast experience as an engineer, physician, professor, former Peace Corps medical officer, and entrepreneur. Known for achieving the improbable, Dr. Jemison also brings a spirit of audacity, innovation and inclusion to 100YSS.
“Yes, it can be done. Our current technology arc is sufficient,” says Dr. Jemison. “100 Year Starship is about building the tools we need to travel to another star system in the next hundred years. We’re embarking on a journey across time and space. If my language is dramatic, it is because this project is monumental. This is a global aspiration. And each step of the way, its progress will benefit life on earth. Our team is both invigorated and sobered by the confidence DARPA has in us to start an independent, private initiative to help make interstellar travel a reality.”
100 Year Starship will bring in experts from myriad fields to help achieve its goal – utilizing not only scientists, engineers, doctors, technologists, researchers, sociologists and computer experts, but also architects, writers, artists, entertainers, and leaders in government, business, economics, ethics and public policy. 100YSS will also collaborate with existing space exploration and advocacy efforts from both private enterprise and the government.
In its first year, 100YSS will seek investors, establish membership opportunities, encourage public participation in research projects, and develop the visions for interstellar exploration. A 100 Year Starship Public Symposium will be held in Houston September 13-16, 2012, inaugurating what will be an annual event open to scientific papers, engineering challenges, philosophical and socio-cultural considerations, economic incentives, application of space technologies to improve life on earth, imaginative exploration of the stumbling blocks and opportunities to the stars, and broad public involvement.
The 100 Year Starship also will include a scientific research institute, The Way whose major emphasis will be speculative, long-term science and technology.
Alongside the Dorothy Jemison Foundation for Excellence, a non-profit organization that promotes science, technology, engineering and mathematics (STEM) awareness and achievement, the principal 100 Year Starship team members are: Icarus Interstellar, a non-profit research and development organization dedicated to the research that will enable interstellar flight; and the Foundation for Enterprise Development centered on governance, innovation, entrepreneurship, technology and R&D based organizational planning, management, and strategic planning. The SETI Institute, a private, non-profit organization dedicated to astronomy, life sciences, education, and public outreach, will hold a permanent seat on the 100YSS Advisory Council.
To sign up for e-mail alerts from 100 Year Starship or learn more about the 100YSS Public Symposium visit www.100YSS.org. Follow 100 Year Starship on Twitter (@100YSS). Contact 100 Year Starship at info@100YSS.org.
The Daedalus Starship. Designed by members of the British Interplanetary Society
in the 1970s – an inspiration for researchers of today. Image courtesy Adrian Mann.
5 Kt Meteor Blast over California
NASA's Goddard Space Flight Center and Astrophysical Journal,
A sonic boom heard in California last week had an out-of-this world origin as ”a large meteoric event” according to NASA’s Meteoroid Environment Office. Scientists now estimate the blast measured in near 5 kilotons or roughly 1/3 the power of the atomic bomb dropped on Hiroshima, Japan during World War II. Bill Cooke of the Meteoroid Environment Office at NASA’s Marshall Space Flight Center, estimates the object was about the size of a minivan, and weighed in at around 154,300 pounds.
A sonic boom heard in California last week had an out-of-this world origin as ”a large meteoric event” according to NASA’s Meteoroid Environment Office. Scientists now estimate the blast measured in near 5 kilotons or roughly 1/3 the power of the atomic bomb dropped on Hiroshima, Japan during World War II. Bill Cooke of the Meteoroid Environment Office at NASA’s Marshall Space Flight Center, estimates the object was about the size of a minivan, and weighed in at around 154,300 pounds.
"Most meteors you see in the night’s sky are the size of tiny stones or even grains of sand and their trail lasts all of a second or two," said Don Yeomans of NASA’s Near-Earth Object Program Office at the Jet Propulsion Laboratory in Pasadena, California. “Large meteors can be seen in the daytime and are many times that size – anywhere from a baseball-sized object to something as big as a minivan.” The meteor appears to be much more valuable than scientists first thought. Meteorite hunters found fragments of the rock, identified by the "fusion crust" that forms when it burns in the atmosphere. NASA and the SETI Institute in Mountain View, California, also mobilized a search team of about 30 scientists to search for the small black rocks. The meteorite turned out to be a very rare type of rock called CM chondrite, which makes up less than 1 per cent of the meteorites that fall to Earth. According to Bill Cooke of NASA's Meteoroid Environment Office at the Marshall Space Flight Center in Huntsville, Alabama, it is not clear whether it is rare because it easily burns up in the atmosphere or there are just fewer of these rocks in space.
13 May 2012
May 10, 2012
SpaceX and Bigelow Aerospace Join Forces to Offer Crewed Missions to Private Space Stations
Hawthorne, CA, and Las Vegas, NV– Space Exploration Technologies (SpaceX) and Bigelow Aerospace (BA) have agreed to conduct a joint marketing effort focused on international customers. The two companies will offer rides on SpaceX’s Dragon spacecraft, using the Falcon launch vehicle to carry passengers to Bigelow habitats orbiting the Earth.
According to Bigelow Aerospace’s President and Founder, Robert T. Bigelow, “We’re very excited to be working with our colleagues at SpaceX to present the unique services that our two companies can offer to international clientele. We’re eager to join them overseas to discuss the substantial benefits that BA 330 leasing can offer in combination with SpaceX transportation capabilities”.
The BA 330 is a habitat that will provide roughly 330 cubic meters of usable volume and can support a crew of up to six. Bigelow Aerospace plans to connect two or more BA 330s in orbit to provide national space agencies, companies, and universities with unparalleled access to the microgravity environment.
“SpaceX and BA have a lot in common. Both companies were founded to help create a new era in space enterprise,” said SpaceX President Gwynne Shotwell. “Together we will provide unique opportunities to entities -- whether nations or corporations -- wishing to have crewed access to the space environment for extended periods. I’m looking forward to working with Bigelow Aerospace and engaging with international customers,” Shotwell explained.
SpaceX’s Dragon spacecraft will be capable of carrying seven passengers to orbit. With the company’s Falcon family of rockets, SpaceX is working to create the world’s safest human spaceflight system.
The companies will kick off their marketing effort in Asia. Representatives from Bigelow and SpaceX will meet with officials in Japan shortly after the next launch of the Falcon 9 and Dragon spacecraft.
About SpaceX
SpaceX designs, manufactures and launches the world’s most advanced rockets and spacecraft. With a diverse manifest of launches to deliver commercial and government satellites to orbit, SpaceX is the world’s fastest growing space launch company. In 2010, SpaceX became the first commercial company in history to put a spacecraft into orbit and return it safely to Earth. With the retirement of the space shuttle, the SpaceX Falcon 9 rocket and Dragon spacecraft will soon carry cargo and astronauts to and from the International Space Station for NASA. Founded in 2002 by Elon Musk, SpaceX is a private company owned by management and employees, with minority investments from the Founders Fund, Draper Fisher Jurvetson, and Valor Equity Partners. The company has over 1,700 employees in California, Texas, Washington, D.C., and Florida. For more information, visit spacex.com.
About Bigelow Aerospace
Bigelow Aerospace is an entrepreneurial company dedicated to revolutionizing space commerce and exploration via the development of next-generation expandable habitat technology. Bigelow Aerospace’s habitats will offer unprecedented amounts of volume on-orbit while providing astronauts with enhanced protection against radiation and physical debris. Bigelow habitats are also lighter and more affordable than traditional rigidized metallic structures. Bigelow Aerospace is the first and only organization to demonstrate expandable habitat technology in orbit, via the successful launch of Genesis I in 2006 and Genesis II in 2007. Bigelow Aerospace has manufacturing facilities and offices in Nevada and Maryland. For more information, visit bigel owaerospace.com.