Space Station Vs. Moon Base

In summary, the idea of putting a station in orbit is more appealing than putting on the moon because it requires less fuel to get there and back, and there are other advantages too.
  • #1
Chronothread
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Why is the idea of putting a station in orbit more appealing then putting on on the moon? I understand the want to test things in low gravity. But what about cost wise? I know that the ISS has to change it's direction every now and then to avoid random junk floating in space, and I understand it would take more fuel to get something to the moon. Is there anything more to the equation then this or is it just that the cost of getting something to the moon and back is much more expensive then maintaining an orbital station?

Thanks for your time.
 
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  • #2
Chronothread said:
Why is the idea of putting a station in orbit more appealing then putting on on the moon? I understand the want to test things in low gravity. But what about cost wise? I know that the ISS has to change it's direction every now and then to avoid random junk floating in space, and I understand it would take more fuel to get something to the moon. Is there anything more to the equation then this or is it just that the cost of getting something to the moon and back is much more expensive then maintaining an orbital station?

Thanks for your time.

It's a long climb out of Earth's gravity well.
It's a long way to the Moon once out.
It's a long way back out of the Moon's well. Why spend all that energy getting out of a well only to plunge back into one?

Other than access to some raw materials, what, if any, are the advantages of the Moon?
 
  • #3
DaveC426913 said:
Other than access to some raw materials, what, if any, are the advantages of the Moon?

One that comes to mind immediately is the use of the far side for telescopic observations. I haven't the numbers but it seems plausible that construction of a scope on solid ground would be cheaper and allow us to have more aperture for a given dollar amount than deploying a space telescope.
 
  • #4
Like I was saying before, I thought one advantage was that they wouldn't have to have the station change it's path to avoid junk every couple of months like they do with the ISS. I was just asking if the main reason was that it required so much energy.

And Nabeshin, apparently they are planning a far side of the moon radio telescope array specifically for the purpose to block out all the interference from Earth. It's coming no time in the near future, but it would seem your suggestion is right.
 
  • #5
Nabeshin said:
One that comes to mind immediately is the use of the far side for telescopic observations. I haven't the numbers but it seems plausible that construction of a scope on solid ground would be cheaper and allow us to have more aperture for a given dollar amount than deploying a space telescope.
Even better, you could construct a truly huge antenna array on the Moon.
 
  • #6
Nabeshin said:
I haven't the numbers but it seems plausible that construction of a scope on solid ground would be cheaper and allow us to have more aperture for a given dollar amount than deploying a space telescope.

D H said:
Even better, you could construct a truly huge antenna array on the Moon.
Again I ask, what advantages does the Moon offer that space does not? Other than access to some materials, you're going to have to haul everything in and out of one more gravity-well.

You seem to be stuck in the mind-set that solid-ground somehow equates with cheaper cost. The Moon is not Earth.

A space telescope will require fewer, lighter materials and be more stable than any ground-based scope.

As for dodging debris, that is only an issue in low Earth orbit.
 
  • #7
You could more easily build an array of optical telescopes designed to do interferometry on the Moon.
 
  • #8
Count Iblis said:
You could more easily build an array of optical telescopes designed to do interferometry on the Moon.
You mean because they would be stable wrt each other? OK, I'll grant that. That's one specific use.
 
  • #9
Nasa is planning for a moon base for 2024 using the orion spacecraft they are currently desinging. I would find that building colonys on the moon would help us because we could build a moon city so it could free up some of the land on earth. Overpopulation is a threat to the survival of the human race. We also could possible use the moon as a space base to launch to Mars and other plantets.
 
  • #10
Yes, this is the other thing that the Moon has over orbit: long-term habitability due to gravity. But the key is long-term.
 
  • #11
You're completely right about the materials part, DaveC. In looking for information about lunar-based telescopes, I found this:
http://www.space.com/businesstechnology/080716-tw-lunar-telescope.html

Which appears to be the most legitimate proposal for any such telescope.

My initial thought was that it would be cheaper to install and maintain an accurate guidance system on a stable surface than use gyroscopes such as those used on Hubble. (Just a thought, I have no information as to the relative cost of terrestrial and space tracking systems)
 
  • #12
The problem with putting a telescope on the moon is that the 'day' is 14days long - so half of the time the sun is in the sky and the rest of the time the Earth is in the way.
Putting a telescope at L2 is much less of a lift and has a lot more sky available
It might be worth it for a few radio frequencies to out a telescope on the dark side of the moon where emissions from Earth are blocked.
 
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  • #13
Actually, stability is not an advantage of being on the moon. The moon isn't 100% stable and there can be nothing as stable as floating in space, with nothing touching the telescope.
 
  • #14
  • #15
DaveC426913 said:
Other than access to some raw materials, what, if any, are the advantages of the Moon?

One limitation of orbital telescopes is the relatively short "integration time." An Earth based scope can keep itself pointed at the same patch of sky for hours and hours -- much longer than Hubble. Conceivably, a Moon based one could do so for days and days. When the object of the game is to collect photons, time is just as important as aperture.

However, I have no idea how moonquakes throw a monkey wrench into that consideration.

Another advantage is that when the far side of the Moon is in darkness, it's really dark. I think the only kind of light pollution you have to worry about is zodiacal light (reflections from all the stuff in farther out in the star system itself).

Of course, whether or not such things justify the expense is another matter.
 
  • #16
Cantab Morgan said:
One limitation of orbital telescopes is the relatively short "integration time." An Earth based scope can keep itself pointed at the same patch of sky for hours and hours -- much longer than Hubble. Conceivably, a Moon based one could do so for days and days. When the object of the game is to collect photons, time is just as important as aperture.
It's the other way around.
A ground based observation (unless you are at the pole) is limited to one night, and because you don't want to be observing through too much air mass (you want the object high in the sky) you are generally limited to 4-6hours.
For an object outside the ecliptic (ie near North/South poles) like the Hubble Deep field you can observe continually. For a telescope not in LEO, like NGST/Kepler, you can observe most of the sky indefinitely.

Another advantage is that when the far side of the Moon is in darkness, it's really dark.
The Dark side of the moon is pointed at the sun for 14days/month - it's only 'dark' in the sense of not seen from Earth (dark=unknown)
 
  • #17
Another advantage of Earth orbit is that the Earth's magnetic field shields ISS from the worst of the Sun's trantrums. We were pretty lucky during the Apollo program. We can't gamble astronauts' lives on "being lucky", and it's pretty darned expensive to loft dense shielding out of the Earth's gravity well. We'd have to be prepared to rely on "being lucky" once again if we put people on the moon to construct facilities, and start excavating caves and tunnels immediately so that we could shield those people with lots of moon-rock. Hard-rock mining is a pretty dangerous occupation. Anybody want to try it in a vacuum in low-gravity while wearing pressure-suits?
 
  • #18
Count Iblis said:
Russ, can you this in space:

http://en.wikipedia.org/wiki/Very_Large_Telescope#Interferometry_and_the_VLTI

And, of course, what I mean is that you want to go far beyond what the VLT can do. So, you want to use more telescopes that are furhter apart so that you get a higher angular resolution and you can image objects that are much fainter.
Absolutely! In fact, that is another example of a shortcoming of the moon vs being in space. Out in space, your options for telescope placement are far less limited. You could, for example, place a telescope on the Lagrange point opposite the Earth from the sun, giving you a 2 AU baseline.

Interferometry is a developing field, but space-based, very long baseline interferometers are on the drawing board, though still a ways' off.

[edit] Here's the scientific paper proposing the concept. It was funded by NASA for a while, but near as I can tell hasn't been funded since 2007. The proposal is for 5 telescopes, one at each Lagrange point: http://web.mit.edu/wsimmons/www/documents/simmons_spie2004.pdf

Here's the author's website: http://newworlds.colorado.edu/

Less ambitious space-based interferometer concepts are in the design phase and will be launched over the next 10 years or so. The success of these could be a stepping stone to the more ambitious 2 AU interferometer.
 
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  • #19
But low Earth orbit is nasty for electronics.
The south atlantic anomaly is a bit of the Earth's magnetic field near Brazil where the radiation belts come a lot lower. When Hubble flies through it the interference takes out some the instruments for about 20% of that orbit.
 
  • #20
mgb_phys said:
The problem with putting a telescope on the moon is that the 'day' is 14days long - so half of the time the sun is in the sky and the rest of the time the Earth is in the way.

Why is that a problem? There is no atmosphere to scatter the light, so just don't point the telescope directly at the sun or Earth when/if they are visible.

russ_watters said:
You could, for example, place a telescope on the Lagrange point opposite the Earth from the sun, giving you a 2 AU baseline.

How would we communicate with it? Have another satellite in Earth's orbit, 90o from Earth?
 
  • #21
turbo-1 said:
Another advantage of Earth orbit is that the Earth's magnetic field shields ISS from the worst of the Sun's trantrums. We were pretty lucky during the Apollo program. We can't gamble astronauts' lives on "being lucky", and it's pretty darned expensive to loft dense shielding out of the Earth's gravity well. We'd have to be prepared to rely on "being lucky" once again if we put people on the moon to construct facilities, and start excavating caves and tunnels immediately so that we could shield those people with lots of moon-rock. Hard-rock mining is a pretty dangerous occupation. Anybody want to try it in a vacuum in low-gravity while wearing pressure-suits?
How does the orion 2024 whatever program plan to address this problem?
 
  • #22
Redbelly98 said:
How would we communicate with it? Have another satellite in Earth's orbit, 90o from Earth?
You could, though if you read on, I found the proposal I was thinking of, which had 5 satellites...

...presumably one could be used to relay data from another, but that seems like a relatively minor issue to me compared with the need for precise station-keeping.
 
  • #23
Coin said:
How does the orion 2024 whatever program plan to address this problem?
Do you have links or references? As of now, I know of no viable proposal (even remotely) to build permanent or long-term temp-habitation facilities any place outside of Earth's magnetic field.

When W tried to polish his credentials by claiming that a goal of NASA should be to send men to Mars, every physicist should have flooded their TV outlets with estimates of the costs of the raw materials for fuel, shielding and engineering costs. At the same time, biologists and medical doctors should have been factoring in the costs of air, water, food, energy for hydroponics, etc, and lofting all that out of Earth's gravity. It's pretty apparent that we can't send our brave Marstonauts out there with years' worth of cans of Spaghettios and ramen noodles. Frankly the people in NASA (and other physical sciences) dropped the ball big-time to let the dope play "visionary scientist president".

There are huge engineering challenges that we face, not the least is low-mass, low-energy shielding systems for vessels in interplanetary space. There is also the huge cost of fuel to get stuff pried away from the Earth, and the "danger factor" that we send people and valuable payloads into orbit sitting on top of complex controlled-bombs that may or may not behave. I love Science Fiction, and a personal favorite is Babylon 5 (with Harlan Ellison consulting). Unlike some, I don't place a lot of faith in the possibility of the plot-line.
 
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  • #24
mgb_phys said:
For an object outside the ecliptic (ie near North/South poles) like the Hubble Deep field you can observe continually.

Oh cool! I didn't know that. That's a really interesting point. Has Hubble always had that capability or was that added in one of the repair/service missions? If I recall correctly, the WFPC can't do that.

mgb_phys said:
The Dark side of the moon is pointed at the sun for 14days/month - it's only 'dark' in the sense of not seen from Earth (dark=unknown)

:smile: Either you didn't understand what I wrote, or you're trying to refute something I haven't claimed. I wrote "[W]hen the far side of the Moon is in darkness, it's really dark." I was just suggesting that night on the far side of the Moon is much darker than night on Earth, and no human-generated light pollution would affect the telescope. I'm not suggesting that the Moon doesn't rotate. :smile:
 
  • #25
turbo-1 said:
We were pretty lucky during the Apollo program. We can't gamble astronauts' lives on "being lucky", and it's pretty darned expensive to loft dense shielding out of the Earth's gravity well.

That's a really good point, but I think you're articulating the reasons why manned spaceflight's days are numbered. Our robots will be doing all the exploring and telescope building. I just wonder if they'll be annoyed at being asked to share with us what they learn.
 
  • #26
Cantab Morgan said:
Oh cool! I didn't know that. That's a really interesting point. Has Hubble always had that capability or was that added in one of the repair/service missions? If I recall correctly, the WFPC can't do that.
The northern and southern 'continous viewing zone' is the angle from north pole that you can see continualy without the sun/earth getting in the way, it just depends on the orbit. The instruments generally don't observe for very long because of cosmic rays, it's better to stack shorter exposures.

I was just suggesting that night on the far side of the Moon is much darker than night on Earth, and no human-generated light pollution would affect the telescope.
Ok, I was just making it clear that the Earth is never in the sky from the back side of the moon but the sun is half the time.
The best place to put a telescope for a good view is at L2, the Lagrange point directly out along on a line from the sun through the Earth.
 
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  • #27
Note that light pollution requires an atmosphere, so the issue isn't any different for the Hubble than for a telescope sitting on the far side of the moon...
 
  • #28
turbo-1 said:
How does the orion 2024 whatever program plan to address this [radiation shielding] problem?
Do you have links or references? As of now, I know of no viable proposal (even remotely) to build permanent or long-term temp-habitation facilities any place outside of Earth's magnetic field.

Well, I find a lot of things centered around the phrase "Lunar Architecture".

NASA planners used the international group's deliberations as well as input from academia, private sector and private citizens as the basis for sketching a U.S. blueprint for a return to the moon. NASA's Lunar Architecture Team, chartered in May 2006, concluded that the most advantageous approach is to develop a solar-powered lunar base and to locate it near one of the poles of the moon. With such an outpost, NASA can learn to use the moon's natural resources to live off the land, make preparations for a journey to Mars, conduct a wide range of scientific investigations and encourage international participation...

As currently envisioned, an incremental buildup would begin with four-person crews making several seven-day visits to the moon until their power supplies, rovers and living quarters are operational. The first mission would begin by 2020. These would be followed by 180-day missions to prepare for journeys to Mars.

The proposed lunar architecture calls for robotic precursor missions designed to support the human mission. These precursors include landing site reconnaissance, natural resource assays and technology risk reduction for the human lander.

So there is a plan, which action was being taken on at some point. I'm not really sure what "viable" has to do with it, I'm just curious what the planners thought was going to happen.
 
  • #29
russ_watters said:
Note that light pollution requires an atmosphere, so the issue isn't any different for the Hubble than for a telescope sitting on the far side of the moon...

I must very respectfully disagree. Earth puts out a lot of radiation, and not all of it is even man-made. For example, there's a spot called the "South Atlantic Anomaly" that's troublesome to electronics in orbit. I believe that the principal advantage Hubble has over ground based scopes is not a light pollution advantage, but that Hubble can see in UV, to which our atmosphere is opaque.
 
  • #30
turbo-1 said:
Do you have links or references? As of now, I know of no viable proposal (even remotely) to build permanent or long-term temp-habitation facilities any place outside of Earth's magnetic field.

When W tried to polish his credentials by claiming that a goal of NASA should be to send men to Mars, every physicist should have flooded their TV outlets with estimates of the costs of the raw materials for fuel, shielding and engineering costs. At the same time, biologists and medical doctors should have been factoring in the costs of air, water, food, energy for hydroponics, etc, and lofting all that out of Earth's gravity. It's pretty apparent that we can't send our brave Marstonauts out there with years' worth of cans of Spaghettios and ramen noodles. Frankly the people in NASA (and other physical sciences) dropped the ball big-time to let the dope play "visionary scientist president".

There are huge engineering challenges that we face, not the least is low-mass, low-energy shielding systems for vessels in interplanetary space. There is also the huge cost of fuel to get stuff pried away from the Earth, and the "danger factor" that we send people and valuable payloads into orbit sitting on top of complex controlled-bombs that may or may not behave. I love Science Fiction, and a personal favorite is Babylon 5 (with Harlan Ellison consulting). Unlike some, I don't place a lot of faith in the possibility of the plot-line.
http://www.cbc.ca/technology/story/2006/12/05/moon-base.html
http://news.nationalgeographic.com/news/2006/12/061204-moon-base.html

Theres 2 links for you to look at.
 
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  • #31
Stratosphere said:
http://www.cbc.ca/technology/story/2006/12/05/moon-base.html
http://news.nationalgeographic.com/news/2006/12/061204-moon-base.html

Theres 2 links for you to look at.
Uhh, neither of those address shielding from solar radiation, nor do they give even cursory attention to the costs of getting adequately-shielded vehicles or temporary habitats to the Moon, or the costs of sending short-term missions there to man the stations. Those are not practical proposals, nor do they reference such proposals - they are pie-in-the-sky articles written for public consumption, and they ignore basic engineering practicalities. It's all well and good to give a name to a theoretical project and promote it in the popular press, but not at the expense of ignoring basic engineering and physics. Tell the public "We're going to the Moon" and then tell some NASA engineers. Their reactions will be a bit different, I guarantee.
 
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  • #32
turbo-1 said:
Uhh, neither of those address shielding from solar radiation, nor do they give even cursory attention to the costs of getting adequately-shielded vehicles or temporary habitats to the Moon, or the costs of sending short-term missions there to man the stations. Those are not practical proposals, nor do they reference such proposals - they are pie-in-the-sky articles written for public consumption, and they ignore basic engineering practicalities. It's all well and good to give a name to a theoretical project and promote it in the popular press, but not at the expense of ignoring basic engineering and physics. Tell the public "We're going to the Moon" and then tell some NASA engineers. Their reactions will be a bit different, I guarantee.

I just gave them as a link to show you that NASA is planning for a moon base. I didn’t put them up there to explain HOW they were going to do that.
http://www.nasa.gov/exploration/home/why_moon.html
If you don't believe the other two links, how a bought one directly from NASA?
 
  • #33
Well, here is another one.
http://www.nasa.gov/exploration/news/GES_FAQ.html

It's all just cheerleading. No feasibility estimates, no engineering studies, no cost-benefit analyses (not even an OOM estimate of project costs), just a bunch of people saying "we want to go to the moon, and this is something we might be able to do when we get there." This is not a project - it is not even the beginnings of a project.
 
  • #34
turbo-1 said:
Well, here is another one.
http://www.nasa.gov/exploration/news/GES_FAQ.html

It's all just cheerleading. No feasibility estimates, no engineering studies, no cost-benefit analyses (not even an OOM estimate of project costs), just a bunch of people saying "we want to go to the moon, and this is something we might be able to do when we get there." This is not a project - it is not even the beginnings of a project.

It is not yet a project yet but it will be in the future. They are developing the spacecraft for going to the moon. They are beginning preparations for starting the project.
 
  • #35
My point was (and remains) that there are always going to be public-relations program within NASA to drum up support for imaginary "feel-good" projects that never have a snowball's chance in He** of getting funding for even the preliminary engineering studies. This is because the simple mass-lofting costs associated with manned missions are already well-understood and they are prohibitive compared to robotic/remotely commanded mechanical probes. Mission-costs can be kept under control by utilizing multiple fly-bys to keep fuel requirements in check, but at the cost of time. You can't do this with manned projects, nor do you want to do Solar fly-bys with humans in that little can. Also, we don't much care if the robotic probes come back to Earth, so we won't need to loft the extra fuel, secondary launch vehicle etc, to get those probes back. We can't be quite as cavalier about manned missions. We need dramatic breakthroughs in propulsion, fuel efficiency, and shielding before we can contemplate more manned missions beyond Earth orbit.

Meanwhile, there are plenty of robotic missions in the pipeline. Do you have an idea how long GLAST was in the pipeline as a serious project with engineering, sensor selection, etc in progress? Even then it was projected to launch in 2005, and that slipped over and over again.
 

1. What is the difference between a space station and a moon base?

A space station is a man-made structure that orbits around a planet or moon, while a moon base is a permanent settlement built on the surface of a moon.

2. Which one is more suitable for long-term human habitation?

A moon base is more suitable for long-term human habitation as it provides a stable and secure environment for humans to live and work in, while a space station is designed for shorter stays and is not as self-sufficient.

3. How do space stations and moon bases get their supplies?

Space stations get their supplies through regular resupply missions from Earth, while moon bases can utilize resources from the moon itself, such as water ice, to sustain human life.

4. Can a space station or moon base support scientific research?

Both space stations and moon bases can support scientific research, but a moon base may have more opportunities for research due to its location on a celestial body and access to resources.

5. How does the cost of building and maintaining a space station compare to a moon base?

The cost of building and maintaining a space station is significantly higher than a moon base due to the complexity and technology needed for space travel and operations. However, a moon base may have higher initial costs for construction and transportation of materials.

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