cross-posted from: https://lemm.ee/post/8135104
Honorable mention: The video was posted to https://lemmy.world/c/mealtimevideos 4 days ago: https://lemmy.world/post/4942489. I did not want to use the YouTube link as the primary link, hence reposting instead of cross-posting.
Further reading about the Lunar Crater Radio Telescope (LCRT):
- https://en.wikipedia.org/wiki/Lunar_Crater_Radio_Telescope
- https://www.nasa.gov/directorates/spacetech/niac/2020_Phase_I_Phase_II/lunar_crater_radio_telescope/
- https://www.nasa.gov/directorates/spacetech/niac/2021_Phase_I/Lunar_Crater_Radio_Telescope/
They want to build the telescope on the far side of the Moon, to shield it from terrestrial (man-made) radiation. Is this premise in peril by other Moon missions? For example, do NASA or other space agencies have plans to build other bases on the far side of the moon, which could emit radiowaves which affect the LCRT?
From one of the ‘further reading’ sources:
I’m also not sure it would be that much more effort. Economically speaking, most of the cost probably comes from rocket launches, which are roughly similar for Moon missions and other far-out space missions. Construction on the Moon has unique challenges (sharp regolith, temperatures), but you get a supporting base for free. If you had to supply and launch support structures, it might be more costly overal.
You don’t need any supporting base when floating around. But you absolutely need to deal with the gravity there. Also, since you don’t just have to reach but land on the moon too, I assume it absolutely takes a lot more effort per mass. Unless you can impact the moon at full speed.
Not to resist gravity, yes. But you need some supporting structure to keep things apart which are meant to be apart, and keep things together so they don’t drift away into space. The general frame of the object, so to say. If you don’t use a natural crater to support your telescope, you need to create some kind of structure to do that job for you.
A similar thing is true for any point in empty space. It’s not enough to get there, you need to decelerate to come to rest when you reached the destination. Yes, when landing on the Moon you need to additionally fight it’s gravity. I still think the energy required to leave Earth vastly outweights the energy required for the final approach. After checking [The Tyranny of the Rocket Equation (NASA)] it seems my estimation was exaggerated, but still right in principle. The most energy will be spent on reaching LEO, and landing on the Moon instead of going to a cis-lunar destination is a difference of 11.5 or 14 (total trip costs) compared to 8 for the initial lift. Numbers from the first table.
Either way, this is amateurs arguing what experts should do. The better approach is probably to dive into their documents to understand their reasoning. Even if we’d agree they should build their telescope in space, that would maybe rather hint at us missing some insight.
Your don’t decelerate to come to rest. You essentially accelerate until you reach the desired height of your orbit, then accelerate some more to turn the elliptical orbit into whichever shape your want it to be. This is as efficient as it gets.
Also, since there is only micro gravity, there is no need for a good structural support. When it can withstand the launch, it is already way overkill for microgravity, at least the systems we currently use. There is a lot of improvement to be made.