Pages

Tuesday, August 31, 2021

The Billionaires Compete And The US Wins The 21st Century Space Race

 

The billionaires compete and the US wins the 21st century space race


Bookmark and Share

Whoever is declared the winner in the so-called billionaire space race, the US wins the new space race. In the new era of space exploration, where commercial companies are taking the lead, they are mostly US-based. Symbolically, British billionaire Richard Branson, the first in space, launched from Spaceport America in New Mexico, where his company is based.

“New Space”, new race

In what is dubbed as “New Space”, the commercial sector is gradually taking the lead in space activities. One of the characteristics of the current New Space era is the so-called billionaire space race, in which billionaires who made their fortune elsewhere invest their wealth and talent in daring projects to accomplish their visions. Elon Musk (PayPal) established SpaceX, Jeff Bezos (Amazon) established Blue Origin, and Richard Branson (Virgin Records, Virgin Atlantic) established Virgin Galactic. Together with the many not-yet-famous space entrepreneurs and startups, they are bringing a boom to space activities.

The model of centralized, government-directed space activities born in the 1960s has, over the last two decades, made way for a new model in which the private sector shares the stage.

On July 11, billionaire Richard Branson rode Virgin Galactic's Unity 22 mission to space, making him the first of the racing billionaires to go to space, and by that launch his company’s space tourism business. Jeff Bezos rode Blue Origin’s New Shepard to space just nine days later. Elon Musk hasn’t yet been to space himself, but his company SpaceX carried astronauts to the International Space Station, and his red Tesla roadster, launched to space in 2018, orbits the Sun. You can follow its current whereabout here.

“Jealousy among teachers increases wisdom” provides the Babylonian Talmud; in the space context, the competition, perhaps jealousy, among billionaires and other space entrepreneurs is bringing a boom to space activities.

The future of space exploration is commercial activities

The commercial space sector is rapidly growing and taking the lead from national space agencies. It is reducing the costs of launch and introducing new activities and business models, including tourism, space-based Internet, factories in space, and manufacturing pharmaceuticals in microgravity.

Harvard business professor Matthew Weinzierl pointed that the model of centralized, government-directed space activities born in the 1960s has, over the last two decades, made way for a new model in which the private sector shares the stage. Three quarters the global space activity ($400 billion) are commercial space revenues, spearheaded by the satellite communications segment. The US already reaps the lion’s share in the traditional space segments, with 44% of the global satellite industry revenues. It is now on track to lead the way also in the new segments.

American pie

A new dataset built at Laval University by Prof. Jean-Frédéric Morin and I as part of the Astro-environmentalism project reveals trends in the global space sector. The dataset includes details on more than 1,500 space actors from around the world and preliminary findings from its analysis were presented in June at the 60th Session of the Legal Subcommittee of the UN Committee on the Peaceful Uses of Outer Space. The data shows the sharp increase in the share of the private space actors compared with the first decades of the space age (1957 onwards), and while there is more geographical diversity today in where actors are based, the US is widening the gap. Between 2010 and 2019 the number of space actors almost doubled (an 89% increase), with more than 86% of them private actors, of which 34% are based in the US; this amounts to five times those based in the second and third places, the UK and China, respectively. The number of new organizations based in EU countries taken together (without the UK) is bit over half of that of the US (56%). The new organizations are significantly smaller than before, with an average size index (combining number of employees and budget) of 2.9 versus 8 in the early days of space exploration. Space startups is a thing.

Whoever is declared winner in the billionaire space race, the commercial sector is handing the US the victory in the 21st Century space race.

While revenues from the space sector are already mostly commercial, the investment side is still dominated by governments, but it is on track to be led by private funds. International government spending has been generally consistent over time, around $80 billion annually, of which 60% is US government spending. Private investment, previously marginal, reached a record $8.9 billion in 2020, despite COVID-19, and it reached new heights in 2021 so far with $5.7 billion in the first quarter aloneA total of $113 billion was invested in the high-tech sector in the US alone in 2019, followed by China with $45 billion. There is no reason why private investments in the space sector will not eventually surpass government spending. Also here, it is the US where most of the venture capital firms investing in the space sector are based, including some who are dedicated to this sector, and where most of the private funds are invested: 55% of the private funds in 2019 invested in US-based firms and 24% in UK-based. Indeed, despite the increase in private funding in China, the US is far ahead. Morgan Stanley estimates that the global space industry could generate revenue of more than $1 trillion or more in 2040. This is a big pie, and, according to current trends, it will be mostly American.

Spaceport America

Symbolically, the first billionaire to ride his rocket to space, Branson, is an Englishman who made his fortune in the UK, but and he took off to space from Spaceport America in New Mexico, where his Virgin Galactic is based.

Being the first does not necessarily mean being the final winner. In the first space race, the Soviet Union had all the initial “firsts,” notably the first satellite (Sputnik 1), first human in space (Yuri Gagarin), first woman in space (Valentina Tereshkova), and the first human-made object to touch the Moon (Luna 2). But it is the US that is largely remembered as the winner of that race. On July 20, 1969, NASA’s Apollo 11 landed humans on the Moon for the first time ever (Neil Armstrong and Edwin “Buzz” Aldrin), handing the US the victory in the first Space Race. While Richard Branson is the first space tycoon to launch himself to space, the race is not over yet, and we might even see new names coming, from previously established billionaires or space startups. Yet, whoever is declared winner in the billionaire space race, the commercial sector is handing the US the victory in the 21st Century space race.


Starship To Orbit Should Be The Tipping Point For Policy Makers

“Starship to orbit” ought to be a tipping point for policy makers


Bookmark and Share

We are watching history in the making.

Starship represents a turning point in human history because it will be the vehicle upon which humans start spreading beyond Earth. When Starship reaches orbit, it will fundamentally bring into question which path forward the United States should take. Given the likelihood that a reusable, very cost-effective, super-heavy-lift vehicle (SHLV) with a high flight rate will become available for the nation to use, we call upon the decision makers in Washington (i.e., the administration, Congress, and NASA) to place Starship at the center of the country’s human spaceflight program after it achieves orbit.

The latest developments

SpaceX is making major progress in Boca Chica, Texas. Company personnel are working aggressively to get an orbital Starship ready. The Super Heavy booster intended for launch has been constructed and its engines mounted. The Starship upper stage was temporarily placed on top of the booster for a fit test. It is unclear exactly when the first orbital launch of Starship will be, but it is certainly sooner rather than later. SpaceX is not only developing the largest and most powerful rocket in history, but they are developing the factory that will crank them out by the hundreds.

SpaceX appears unstoppable

It seems that SpaceX is in a position to where it has the financial capability to see Starship development through to completion. NASA’s $2.9 billion contract with NASA has recently been confirmed.

Starship will cause a turning point for humanity as we begin spreading beyond Earth. It is at the level of any of the great moments of exploration and settlement.

But SpaceX is even positioned to have sufficient funding independent from NASA. Not only is Elon Musk often among wealthiest people in the world, but SpaceX is also able to raise very large amounts of funding for Starship development. If Starlink pans out as intended, SpaceX anticipates having annual revenue equal to the entire budget of NASA. Long gone are the days when SpaceX struggled to ensure its own financial survival. When a Starship crashes during development, no serious person questions whether SpaceX can continue. Even the existing production system can crank out more vehicles in a month or two, assuring no long delays in the test program due to setbacks. There’s always the next prototype nearing completion. It would seem that SpaceX can weather things even if the Starship development path going forward is challenging.

The significance of Starship

SpaceX is completely rewriting the book when it comes to rockets. A fully and rapidly reusable SHLV questions the competitiveness of almost all other rockets. Take, for example, SpaceX’s plan to place 400 Starlink satellites into orbit per launch in which most of the cost is only propellant. Who could compete with that? All the existing expendable rockets worldwide simply won’t be able to compete with Starship. And those companies or countries that seek to develop fully reusable rockets are years behind SpaceX and will find that SpaceX will have moved well forward by the time their competitors achieve full reusability. It’s hard to catch a target that is both ahead of you and accelerating away.

But there is an important historic significance to Starship as well. As noteworthy as the first woman and the first person of color on the Moon is, the real historic prize to be seized is the establishment of humanity’s first foothold off Earth. Starship will cause a turning point for humanity as we begin spreading beyond Earth. It is at the level of any of the great moments of exploration and settlement.

Levels of Starship success

Just because SpaceX intends to produce a fully and rapidly reusable SHLV doesn’t mean its success is inevitable. SpaceX may get Starship to orbit, but after bulking up with a heat shield and carrying that landing burn propellant, how much payload will it be able to get to orbit? It is a rather important question. If its payload to LEO is moderately below 100 metric tons then this affects how many propellant tanker launches will be needed to go beyond LEO. After a while it becomes excessive.

Yet, full reusability is not the only level of success that Starship can achieve. And even the most modest success questions the need for SLS. If Starship can reach orbit with sufficient payload, even without reuse of the Super Heavy booster and without reentry, landing, and reuse of Starship, it will still be a far more cost-effective SHLV than SLS. If Starship is also able to reach orbit and successfully retrieve its Super Heavy booster, this will make it dramatically more cost-effective than SLS. And if Starship achieves orbit, successfully retrieves its Super Heavy booster, and safely reenters and lands the Starship, then SLS becomes a strange historical footnote: terribly expensive, flew a few times, and then retired.

The issue of human rating

The only remaining valid argument for SLS is that it will probably achieve human rating for deep space missions before Starship achieves the same level of safety. If urgency is more important than sustainability, then perhaps there’s a case for continuing the development and use of SLS before Starship achieves human rating.

If the Lunar Starship ever docks with Gateway, the size comparison with Gateway will appear silly and beg the question as to whether Gateway is actually necessary.

But the SLS/Orion system is intended to send fewer astronauts to lunar orbit than could fit within a Dragon or Starliner capsule. And Orion can also get to LEO using different approaches than on an SLS, including on a Delta IV Heavy or Falcon Heavy. It will be interesting to see how the crew for the dearMoon mission are launched to orbit because the fastest and safest way of doing this would be to launch the crew on one or two Dragons and then transfer them over to Starship. If the Lunar Starship is safe enough to take astronauts from the Gateway to the lunar surface and back, wouldn’t it be safe enough to ferry astronauts between LEO and the Moon as well? If NASA was open-minded to all potential architectures, it could see how the same missions could be accomplished using SpaceX alone with equivalent safety and at far, far lower costs.

Human-rating Starship

SpaceX has experience with human rating vehicles (Falcon 9 and Dragon) and they are fully committed to developing Starship to the point where they can launch crew starting with the dearMoon mission slated for 2023. And of course, since SpaceX has a contract worth $2.9 billion to develop Starship to the point where they can ferry astronauts from the Gateway to the lunar surface and back, then wouldn’t it be safe to ferry astronauts from LEO to the Moon? And, when that point in time is reached, even if Starship isn’t yet human rated for the launch phase, there are safe ways of getting astronauts to LEO, namely, in a Dragon and/or Starliner capsule. So, one could easily envision an Earth-Moon architecture that doesn’t need SLS for heavy cargo, nor to launch the Orion capsule to LEO.

size comparispo
Size comparison of Starship, Gateway, and Orion. (credit: Mack Crawford)

Awkward moments

There will be several moments which will prove awkward for NASA. First, when Starship deploys up to 400 Starlink satellites at a time, it will be clear that the heavy cargo capability of SLS can be provided by another system for pennies on the dollar.

Second, if the Lunar Starship ever docks with Gateway, the size comparison with Gateway will appear silly and beg the question as to whether Gateway is actually necessary. Does this even make sense? Couldn’t two Starships simply dock with each other and transfer propellant from one to another. Is there really a need for a middleman?

The third moment will be when SpaceX conducts private lunar flyby missions at dramatically less cost than what NASA is planning on spending for launching crew to the Gateway. The inevitable question that reporters and lawmakers will ask is, “Why not use the $3 billion a year spent on SLS and buy dozens of Starship launches?” Why indeed?

Finally, when two Starships dock with each other and transfer propellant, it will have a capability well beyond the SLS. I have spoken with aerospace engineers who work on cryogenic propellant transfer, who agree that it probably won’t be a particularly difficult achievement.

Expiration date on SLS

Here is the tentative timeline for the first three Artemis missions:

  • Artemis 1 – no earlier than (NET) November 2021 - Uncrewed orbit of the Moon.
  • Artemis 2 - NET September 2023 - Crewed lunar flyby.
  • Artemis 3 - probably after 2024 - Crewed mission to the lunar surface, probably not going through the Gateway.
So, what should the decision makers do once Starship achieves orbit? They should commit to fully utilizing Starship’s capabilities.

So, what should the decision makers in Washington do when faced with the competing options of the expensive and old, but proven safety, of legacy hardware (i.e. the SLS) versus a much more cost-effective approach (i.e. Starship) that will, within a few years, provide similar levels of safety? At some point, it will be obvious that SLS is an unnecessarily expensive alternative to Starship. One might argue that a government SHLV is needed as a backup to the private Starship. But, given how many Starship flights could be purchased for just one SLS flight, that argument is ultimately untenable.

Will NASA risk its relevance?

For a very long time, NASA has been in the driver’s seat when it comes to the nation’s human spaceflight program—and it still is. But for how long? Depending on how successful Starship becomes, NASA could find itself in the awkward position of losing the leadership for both lunar and Martian human spaceflight. In this case, NASA would not be losing it to a competing country (aka China) but instead it would simply become irrelevant when countries and private individuals are able to purchase tickets directly from SpaceX. Sure, NASA could still do planetary probes and rovers, but to continue to lead in space, it needs to continue to play a leading role in human spaceflight.

What should the space policy decision makers do?

Given everything discussed above, space policy makers really ought to accept the reality of where things are headed. When Starship achieves orbit, then the handwriting is on the wall for SLS. The sooner that we begin the transition to Starship at the center of the nation’s human spaceflight program, the better.

The old adage says, “If you can’t beat ’em, join ’em.” So, what should the decision makers do once Starship achieves orbit? They should commit to fully utilizing Starship’s capabilities. NASA should do an evaluation of what vehicles are actually necessary. When allowed to do this in the past, they concluded that Falcon Heavy was sufficient for the Europa Clipper mission instead of SLS. They also concluded that Artemis 3 could bypass the Gateway and go directly to the Moon. At one point, former NASA administrator Jim Bridenstine even described a lunar surface architecture using a combination of Falcon Heavy and Delta IV.

Instabase
Illustration of the InstaBase – a fully inflatable initial base able to support an initial crew of eight. (credit: The Space Development Network)

Illustration of the InstaBase – a fully inflatable initial base able to support an initial crew of eight (credit: The Space Development Network)

But the decision makers should also consider a dissimilar, redundant Earth-Moon transport system using hydrolox engines that can eventually utilize the lunar polar ice for propellant. Blue Origin is the logical company to do that. Given Starship’s anticipated capability (i.e. 100 tonnes of cargo or more than 100 passengers to the lunar surface), NASA’s limited, exploration orientation needs to give way to where that level of capability is leading: a large, international lunar base that can eventually become a settlement. Any competing Earth-Moon transport system needs to rise to that level of settlement capability and the decision makers should require that.

Surface systems

Frankly, SpaceX doesn’t need the full $2 billion per year that SLS gets. It’s making faster progress with less. But given that Starship is bringing a future with a large lunar base to our foreseeable future, NASA should really get going with completing surface systems to make sure that it is ready to fully utilize Starship’s capability as soon as it becomes available. We need to stop the endless study phases and instead funding work on of all sorts of alternate concepts. We need to act like we are facing a deadline (which we are) and choose a final surface architecture and develop it. As for habitats, we will quickly need very large habitats soon because Starship will be able to deliver perhaps a hundred residents at a time. An inflatable habitat massing 100 metric tons would have a footprint of about 21,000 sq. ft. (half an acre), not counting equipment to be shipped and installed later. We need to set aside the endless 3D-printing challenges for later and proceed with inflatables, a technology with three examples in space now. Lunar habitats and supporting infrastructure are a much better way to spend the $2 billion a year.

International leadership

The decision makers need to recognize that Starship will provide a remarkable foreign policy opportunity. Per-seat prices on a fully reusable Starship means that even relatively small countries could purchase a ticket for their national astronauts to explore the surface of the Moon on behalf of their own citizens and in their own language. If there is a growing international lunar base, many countries may want to participate.

When Starship achieves orbit, that moment should cause them to fundamentally rethink our human spaceflight program and make decisions to take full advantage of this most remarkable opportunity.

America should actively take the lead in opening up the Moon (and then Mars) to the nations of the world by encouraging national pride and leading in the development of an international lunar base in which freedom and liberty are the foundational principles as humanity starts to spread beyond Earth. The goodwill generated by this will be a tremendous foreign policy achievement. Given the number of countries that will be able to afford to send their astronauts, we need to have a much broader view of the Artemis Accords than the dozen countries signed up so far.

Conclusion

Starship really does change everything, not just for lunar exploration but for the next step for humanity. The decision makers in Washington need to accept where Starship is taking us. When Starship achieves orbit, that moment should cause them to fundamentally rethink our human spaceflight program and make decisions to take full advantage of this most remarkable opportunity.


Note: we are using a new commenting system, which may require you to create a new account.

Saturday, August 21, 2021

SpaceX Starships Design Error, Inspiration 4, Blue Origin vs SpaceX, Ari...

As Asteroids To Hit Earth????

 

The Crasher

Scientists at NASA recently figured out when the 1,640-foot-wide Bennu asteroid will swing by Earth and also when it will hit our planet, the Independent reported.

The space agency used data from the Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (OSIRIS-REx) spacecraft to study the asteroid’s movements from now until 2300.

OSIRIS-REx has spent two years analyzing Bennu’s size, shape and composition from close proximity. The space probe is set to return to Earth in 2023 with a sample of the giant space rock.

In their findings, astronomers said the celestial body will swing by in 2135. This close encounter will allow scientists to better forecast how the planet’s gravity affects the asteroid’s path around the Sun – and a future potential impact.

The team reported that Bennu is set to crash on Earth on Sept. 24, 2182 but the chances of an impact are one in 2,700 – and one in 1,750 through the year 2300.

Even if it did crash, it wouldn’t be world-ending: It would create a crater 10 to 20 times its size. Even so, the area of destruction would be about 100 times the size of the crater.

Although researchers are not worried, they noted that Bennu’s course could be affected by other forces around the solar system. Still, the chances are slim, the Associated Press reported.

For now, there is nothing to worry about.


Friday, August 20, 2021

Dear Elon Musk, please save Artemis with this innovative spacesuit!

What would it take to dump Starliner for Dreamchaser?

The Martian Life

 





Living the Martian Life

Fans of the science fiction book and movie “The Martian” now have the chance to experience what it’s like to live alone on Mars, the Associated Press reported.

Earlier this month, NASA began taking applications for four people to live in a simulated version of the red planet for a whole year.

The four spacefarers will spend their time in Mars Dune Alpha, a 1,700-square-foot Martian habitat, created by a 3D printer, which is hosted by the Johnson Space Center in Houston, Texas.

The paid volunteers will experience a make-believe Martian exploration mission, including spacewalks, limited food and resources and equipment failures. Food will comprise of ready-to-eat space food but the participants will also be able to grow plants – similar to the movie.

“We want to understand how humans perform…,” said lead scientist Grace Douglas. “We are looking at Mars-realistic situations.”

Meanwhile, the application is restricted to specific individuals: They must be American citizens or permanent US residents with a master’s degree in a science, engineering or math field, or have pilot experience. The potential Martians need to be between 30 and 55 years old, in good health and not prone to motion sickness.

Former Canadian astronaut Chris Hadfield said that the selective application shows that the space agency is looking for people who are similar to astronauts. Apparently, past Russian efforts at a pretend Mars mission didn’t go well – the people were too normal, he said.

Click here to become a Martian.