Nobody can even come up with a coherent reason for any of these proposals to exist. Even the ISS is more of a political instrument than a real science thing. NASA likes to say its about studying how to help humans live in space, but those results were in decades ago: more than a few months in zero-g wrecks people. So why are we still trying to build old modular Salyut/Mir derivatives instead of trying to figure out the minimum spin humans need to stay healthy? Because the whole point is to do familiar safe things while providing full time jobs for ground control.
Extended space spays doesn't really wreck people, it's just that your body adjusts to the new environment so your strength decrease, your bone density decreases, your orientation mechanisms shift to 6 degrees of freedom, and so on. Of course when you get back to Earth you're body again has to go through a readjustment phase because those previous adjustments are now unfit for the new environment, but it's nothing beyond that. It'd be interesting to see what an extremely long stay of like a decade+ would do, but that's a major ask of anybody not only in time commitment but also because it's basically asking whether or not the transition would be fatal, and the answer is unclear.
As for a spinning station, that's something NASA will probably never do. They're extremely risk averse and you're opening up an unknowable, but very large, number of new possible failure scenarios there - many of them likely catastrophic. If anything that's something of an argument for genuine private stations who may have different levels of risk tolerance. Or we can just wait for China, because they'll 100% do it and probably relatively soon.
The results from ISS are much more pessimistic than you say, suggesting some irreversible damage besides the reversible changes, but I am lazy now to search links to the research articles. The weakening of the skeletal muscles is not the worst, but the deterioration of the heart muscle.
However, the research done on mice on ISS suggests that the undesirable effects can be mitigated by creating an artificial gravity (i.e. rotation) lower than on Earth, e.g. of 2/3 of Earth's gravity.
The failure scenarios for rotating spacecraft need not be more severe than for non-rotating spacecraft. For instance if 2 or more spacecraft, which can be also used independently, are connected with cables to enable them to rotate around the common center of mass, if everything is designed carefully the failure of the coupling system should not have any other consequences than the loss of the artificial gravity and from then on the failure risks would be the same as for non-rotating spacecraft.
As stated elsewhere, there's a very recent study [1] on astronaut heart health that's quite relevant. They studied the cardiovascular health of astronauts for 5 years after their return from long-duration stays on the ISS. They were all perfectly healthy.
For one obvious problem with rotation systems, stations need to be regularly boosted. You'll also need to occasionally reboost the local rotation. This sort of basic stuff is already fairly complex with a static station, and becomes exponentially more so with a local rotation going on. Even moreso because you want to be relatively fault tolerant in case of a partial or failed boost. Then you need to compensate for impacts, docking and undocking, and much more.
It's viable and almost certainly a solvable, but NASA is not the appropriate organization to do so. Their risk aversion makes it unlikely that they'll ever be doing much of anything revolutionary where failure could be catastrophic. They're having a tough enough time just trying to recreate what we already did 50+ years ago.
It's not just adjustment, there's a decent amount of evidence it's just bad for your health in general, apart from the issues when coming back to earth. Stuff like your circulation also gets messed up.
I'm active in this topic and have never heard anything similar to what you've mentioned. And in looking this up, there's a very recent study [1] that's quite relevant. They studied the cardiovascular health of astronauts for 5 years after their return from long-duration stays on the ISS. They were all perfectly healthy.
To expand on that - there are many body systems that depend almost entirely on the 1g glodilocks zone. Lymphatic systems movt , venous blood returning deox blood to the heart and even some digestive processes. Keenly dependent on a g value that allows proper muscle tone/function to the systems at play.
Too little or too much and and human life becomes non-viable.
Throw in the effect of ping ponging between microgravity and 1g and the issues multiply.
At risk of crassness - human lives are pretty cheap and there are plenty of people willing to take the hit for a chance to be in space for an extended timeframe. Meanwhile building something with enough spin and shielding is a huge ask
If manned stations aren't doing any particularly unique research, especially research that couldn't be done with automation, why spend huge resources on them?
Maintain american capacity to put technicians in low earth orbit. People forget a big part of the shuttle mission for example was to capture and put technicians not just on your satellite but any satellite the shuttle was capable of intercepting and getting into the bay. Consider the fact that the shuttle didn’t really die, in fact the airframe form is still flown but its mission is now classified.
It's cheaper to launch replacements than it is to do maintenance (at least, if you plan it that way).
There are not classified shuttle equivalents launching, not sure what you are talking about there. The X37 has the capability to land, but it is not manned and is tiny compared to the shuttle.
X37 is what I am talking about. Same form: big flying satellite workshop. Just reduced footprint, and obviating the human so it could spend years in orbit and maximize cargo. But if they decided they needed a bigger X37 for larger bay space seems it could be done pretty trivially given shuttle experience. Or one stocked with a couple of those robots that just goosewalked with Melania Trump contorted into some packaging.
If the shuttles ever tinkered with any satellites they weren't meant to, it was relatively boring ones in low inclination orbits, not the really cool ones in earth observing polar orbits. We know this because the shuttles never went to those orbits.
if they're genuinely out of research ideas to test in space
A bigger problem is lack of expertise. Astronauts are not specialist in whatever is the topic of the current experiment. You need probably like 5 years of training (assume the second half of the undergraduate degree, and perhaps the first half of the PhD). So experiments must be fully automated except for a button to turn they on and off.
Lots of research has technicians doing the actual experimental tasks, your argument would benefit from even a short list of experiments that have not been done because astronauts couldn't be expected to handle it.
Meatbags are versatile but really, really expensive. They require a really vast support system, and it has to be highly redundant because the cost of a loss is so high.
You can send up a lot of less versatile bots for the price of one meatbag.
An entirely different form of research could be done by sending large quantities of normal people into space. Astronauts are such a small sample size (and so thoroughly vetted) that you get a different statistical view.
We don't even know how much spin we'd need, and this is an important question to answer if lunar or martian habitats are something we're serious about. Maybe enough spin to match lunar gravity is enough, maybe less, maybe a lot more.
Obviously, we know that the gravity of Earth is sufficient.
But the results make probable that two thirds of the gravity of Earth might be enough, while the gravity of Mars may create some problems and the gravity of the Moon is very likely to be insufficient, so the time spent on the Moon must be limited, though not so much as on the ISS.
I agree with the previous poster that any spaceship designed for carrying humans to Mars or even farther must be designed to spin and anyone who accepts to go on something else is stupid.
Making a spinning spaceship may be cheap if dual bodies or one body and a counterweight are used. It is likely that the safest solution would be to have 2 identical spacecraft, which could also be used independently but which could be coupled with cables to spin around the common center of mass at a distance big enough to create enough gravity at a low rotation speed.
The problem is not the price but the fact that nobody has tested how difficult is to control such a configuration (avoiding oscillations and instabilities) and how difficult is to solve problems like docking in a manner that does not waste energy (i.e. without changing the rotation speed of the more massive spinning spacecraft, which can be done by having 1 or more docking ports on the rotation axis, like on the hub of a wheel; in the case when the rotating spacecraft would be made with 2 bodies or a body and a counterweight that would be linked with cables, one could have the equivalent of an elevator for transporting crew and equipment from the docking port to the main body or bodies).
But someone must build and test such a spacecraft, otherwise we will never learn how to do it right and which are the real problems that are hard to predict in a simulation.
I'm sure there's plenty of people who say that (on earth), but how many are going to have buyer's remorse after the first month? We tend to only send the most exemplary humans to space because you have to be in excellent physical and mental health just to weather the difficult conditions.
I agree that a "long term fractional g spin test" is one of the most valuable things a LEO station can do. But there are others too.
For example, medical interventions against zero-g decay can be tested in any microgravity, spin or no spin. Development of in-space manufacturing and assembly can happen on any sufficiently capable space station.
All of that, however, requires a good amount of ambition. And I'm not sure if NASA under the current political system can deliver ambition.
"Body" is a pile of elaborate biochemistry. The muscles don't somehow evaporate when you stop exercising - it's the processes of the body itself that trim the "excess" muscle tissue.
And if it's the body doing that, you can, in theory, find a biochemical way to make it stop doing that.
"Physical damage and weakness can’t be stopped by a pill."
If you rephrase that to correct English then it would make sense. We aren't trying to stop physical damage or weakness we are trying to prevent it from happening. Pills can prevent many things that cause this.
Nobody cares about ground control. They care about aerospace industry in their states. Public space programs aren't about science and engineering, no they are primarily about jobs. We burn enormous capital in strange ways in order to divert a small amount of capital into useful places. Its the only way to get it done, so I can live with it.
NASA is the goverment agency routinely favored by the general public. They can't meaningfully reduce funding, now that "race to space" with China is heating up.
Most of the public don't know there's another space race and would probably tell you that Artemis is a new brand of deodorant or something. Senators don't care about space fans, they just want NASA to be a consistent reliable jobs program that doesn't throw any curve balls (hence NASA's [nominal attempts to have a] low tolerance for risk.)
Unlike other government agencies, space fans are electorally meaningful number of people, as far as I know. Wait till China start scoring firsts with manned Moon expeditions and journalists start explaining that Senate not caring, and situation will get interesting, uncomfortably so.
Right!
And because China has a good chance of pulling of a moon and then mars landing first, they are lurching into, hmmmm,ok,they are lurching flat out trying to bluster up a program without disturbing the space grift industry, ie: SLS , Shuttle Leftover Systems
and the whole thing disolves into cringe
It's pretty wild to me that in both the article (written by Eric Berger, who really knows his stuff and did two fantastic books on the history of SpaceX and the rise of new space) and the first 31 comments made here on HN as I write this that a Find for one word has zero results: "starship". That's the overwhelming behemoth elephant in the room. For the purposes of launching/building a space station, it doesn't matter if Starship can't reenter, or refueling doesn't work or any of the other hard problems. It just needs to get to orbit. Which it has proven it can. And that means that any space station developed using anything before that will be rapidly completely obsolete from a commercial perspective. Starship will just offer so much more volume and mass for the same cost or less. NASA may want very hard to hit their 2030 deadline, but the technology may simply not line up to do it on the budget they want and desired partner concerns, same as how the retirement of the Space Shuttle didn't line up with American private launch (though of course in the end that has made it and been a big win). No company that actually wants to make money is going to risk billions on something that somebody else can lap them on by an order of magnitude in a few years or less.
I suspect that of "continuous presence in low orbit", "longer term new capabilities", "in budget", and "commercially successful" NASA is going to be forced to pick one or two and that's what they're resisting. Rushing things along almost always costs a lot of money and features. If you want to hit a budget and features then you have to be willing to wait for the various bits to line up and preferably spend some time experimenting and exploring new capabilities and strategies before big hardware commitments. There's a lot of moving parts here to think through. This would all be true even if that was NASA's only concern, vs going to the Moon and all the normal and importance science and so on they're getting pushed on.
I think even experts like Eric are now being conservative on Starship because the program is genuinely in a tough spot.
For most satellites/space stations, you need a proper payload deployment mechanism. The pez dispenser mechanism was chosen because opening the entire payload bay and closing it back up for reentry is a tough problem. For now it has been put aside to focus on the goals for Artemis, but that also means not being able to launch stuff other than Starlink.
Starship is currently still stuck in development hell, Musk is already backing off from his Mars plans, SpaceX is moving to distractions and going public (something they previously claimed would not be done).
To me, these moves do not suggest confidence in Starship's ability to live up to its advertised capabilities.
The Starship is also built to house astronauts for longish trips. It’s not a stretch to think of it as a larger Skylab station. If the can figure out how to attach six or eight of them in a ring with bridges and spin, they could have the artificial gravity station that’s been the stuff of science fiction (and the movie The Martian)
I don't think Starship has gotten to orbit yet. It's gotten to altitude but not speed. That's a very big deal, because slowing down from that speed is a massive challenge unto itself.
Orbit is scheduled for the test after next, if all goes well.
They don't really need Starship just for orbit. They've already got ships that get to the ISS and back. They really do need to get Starship to orbit or their plans really will be hosed.
NASA hasn't had a proper goal or mission for decades. That's their problem. And the spaceflight goal that everyone wants -- making things cheaper -- is not something that government agencies are particularly good at producing.
Well, I'm happy about NASA's idea for private space stations. Maybe I'm not happy with the timing, but I definitely think that this is the future. If you make space stations a valid, self-sustaining industry, that frees up budget for NASA to pursue other non-economically viable missions like going to the Moon and to Mars. It's like someone else's comment about the space shuttle: I was sad to see it go, and maybe it was premature, but private space transport is a more economical way of reaching space.
It seems obvious to me there will be methods and techniques using solar energy to disassemble asteroids and output large structures such as cylinders or spheres that will then become habitats. Example given a spherical grid one kilometer in diameter, apply a charge to it, place several tons of steel at the the center. Focus a mirror at the steel, vaporize and electro deposit the steel on grid. Voila steel sphere.
I’d like to see someone working on this, could be done in LEO.
Not enough opportunity to grift off the taxpayers. Private enterprise will focus on faster, cheaper, better while the government and its contractors focus on keeping the gravy training running.
84 comments
As for a spinning station, that's something NASA will probably never do. They're extremely risk averse and you're opening up an unknowable, but very large, number of new possible failure scenarios there - many of them likely catastrophic. If anything that's something of an argument for genuine private stations who may have different levels of risk tolerance. Or we can just wait for China, because they'll 100% do it and probably relatively soon.
However, the research done on mice on ISS suggests that the undesirable effects can be mitigated by creating an artificial gravity (i.e. rotation) lower than on Earth, e.g. of 2/3 of Earth's gravity.
The failure scenarios for rotating spacecraft need not be more severe than for non-rotating spacecraft. For instance if 2 or more spacecraft, which can be also used independently, are connected with cables to enable them to rotate around the common center of mass, if everything is designed carefully the failure of the coupling system should not have any other consequences than the loss of the artificial gravity and from then on the failure risks would be the same as for non-rotating spacecraft.
For one obvious problem with rotation systems, stations need to be regularly boosted. You'll also need to occasionally reboost the local rotation. This sort of basic stuff is already fairly complex with a static station, and becomes exponentially more so with a local rotation going on. Even moreso because you want to be relatively fault tolerant in case of a partial or failed boost. Then you need to compensate for impacts, docking and undocking, and much more.
It's viable and almost certainly a solvable, but NASA is not the appropriate organization to do so. Their risk aversion makes it unlikely that they'll ever be doing much of anything revolutionary where failure could be catastrophic. They're having a tough enough time just trying to recreate what we already did 50+ years ago.
[1] - https://journals.physiology.org/doi/full/10.1152/japplphysio...
[1] - https://journals.physiology.org/doi/full/10.1152/japplphysio...
There are not classified shuttle equivalents launching, not sure what you are talking about there. The X37 has the capability to land, but it is not manned and is tiny compared to the shuttle.
>research that couldn't be done with automation
I'd think there is room for both. Automation makes sense, but don't think the versatility of meatbags is entirely there yet.
>
if they're genuinely out of research ideas to test in spaceA bigger problem is lack of expertise. Astronauts are not specialist in whatever is the topic of the current experiment. You need probably like 5 years of training (assume the second half of the undergraduate degree, and perhaps the first half of the PhD). So experiments must be fully automated except for a button to turn they on and off.
You can send up a lot of less versatile bots for the price of one meatbag.
"0.33g mitigates muscle atrophy while 0.67g preserves muscle function and myofiber type composition in mice during spaceflight"
https://pmc.ncbi.nlm.nih.gov/articles/PMC12985678/
Obviously, we know that the gravity of Earth is sufficient.
But the results make probable that two thirds of the gravity of Earth might be enough, while the gravity of Mars may create some problems and the gravity of the Moon is very likely to be insufficient, so the time spent on the Moon must be limited, though not so much as on the ISS.
I agree with the previous poster that any spaceship designed for carrying humans to Mars or even farther must be designed to spin and anyone who accepts to go on something else is stupid.
Making a spinning spaceship may be cheap if dual bodies or one body and a counterweight are used. It is likely that the safest solution would be to have 2 identical spacecraft, which could also be used independently but which could be coupled with cables to spin around the common center of mass at a distance big enough to create enough gravity at a low rotation speed.
The problem is not the price but the fact that nobody has tested how difficult is to control such a configuration (avoiding oscillations and instabilities) and how difficult is to solve problems like docking in a manner that does not waste energy (i.e. without changing the rotation speed of the more massive spinning spacecraft, which can be done by having 1 or more docking ports on the rotation axis, like on the hub of a wheel; in the case when the rotating spacecraft would be made with 2 bodies or a body and a counterweight that would be linked with cables, one could have the equivalent of an elevator for transporting crew and equipment from the docking port to the main body or bodies).
But someone must build and test such a spacecraft, otherwise we will never learn how to do it right and which are the real problems that are hard to predict in a simulation.
>We don't even know how much spin we'd need,
Forgive my ignorance on the topic, but surely "same as earth" would be the starting point? With everything less being a trade-off that is suboptimal
For example, medical interventions against zero-g decay can be tested in any microgravity, spin or no spin. Development of in-space manufacturing and assembly can happen on any sufficiently capable space station.
All of that, however, requires a good amount of ambition. And I'm not sure if NASA under the current political system can deliver ambition.
> For example, medical interventions against zero-g decay
This seems obvious but I’ve never heard of anyone working on a drug to address it. Strapping astronauts to a treadmill yes, pills no.
And if it's the body doing that, you can, in theory, find a biochemical way to make it stop doing that.
If you rephrase that to correct English then it would make sense. We aren't trying to stop physical damage or weakness we are trying to prevent it from happening. Pills can prevent many things that cause this.
I suspect that of "continuous presence in low orbit", "longer term new capabilities", "in budget", and "commercially successful" NASA is going to be forced to pick one or two and that's what they're resisting. Rushing things along almost always costs a lot of money and features. If you want to hit a budget and features then you have to be willing to wait for the various bits to line up and preferably spend some time experimenting and exploring new capabilities and strategies before big hardware commitments. There's a lot of moving parts here to think through. This would all be true even if that was NASA's only concern, vs going to the Moon and all the normal and importance science and so on they're getting pushed on.
For most satellites/space stations, you need a proper payload deployment mechanism. The pez dispenser mechanism was chosen because opening the entire payload bay and closing it back up for reentry is a tough problem. For now it has been put aside to focus on the goals for Artemis, but that also means not being able to launch stuff other than Starlink.
Starship is currently still stuck in development hell, Musk is already backing off from his Mars plans, SpaceX is moving to distractions and going public (something they previously claimed would not be done).
To me, these moves do not suggest confidence in Starship's ability to live up to its advertised capabilities.
NASA finally got a leader with a clear vision, and with technologies like Starship and Blue Origin's New Glenn getting ready, the future is bright!
ISS is no longer the frontier, and I am glad NASA is focusing its resources on the future.
Orbit is scheduled for the test after next, if all goes well.
They don't really need Starship just for orbit. They've already got ships that get to the ISS and back. They really do need to get Starship to orbit or their plans really will be hosed.
I’d like to see someone working on this, could be done in LEO.
this is the lost decade of science and progress unfortunately