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Would mining huge amounts of resources on the Moon change its orbit?


Could humans alter the moon's orbit significantly with current technology?What kind of event, if any, would knock the moon off its orbit, without destroying it?Could over-colonization throw our moon out of orbit?How would a nuclear blast on the moon affect its orbit?What kind of event, if any, would knock the moon off its orbit, without destroying it?Could a moon have its own satellites visible from the planet it orbits?How big can a moon be where you can physically jump out of its orbit, to its planet?Exoplanetary Review: Rock StormsHow would a nuclear blast on the moon affect its orbit?How plausible is this as a corporate motivation?Plausible way for the Sun to lose huge amounts of mass?Making a Planet Seem UninhabitableGiving a Planet SunburnWhat effect will mining on the Moon have long term?













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$begingroup$


Imagine that humanity builds mining facilities on the moon. We know that the moon has Helium-3 which could be used as fuel for fusion reactors. Also, there are a lot of other resources which could be used for building ships and buildings instead of transporting them from Earth.



Thousands of tons of metals will be mined from the moon in order to sustain a giant fleet of military, civilian and scientific ships for further colonization of our Solar System.



Because all of these actions, the moon will start to lose its own mass. Would this have some kind of impact on its orbit? If it is, how severe would the changes be?










share|improve this question











$endgroup$


This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.









  • 7




    $begingroup$
    Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
    $endgroup$
    – Erik
    16 hours ago










  • $begingroup$
    I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
    $endgroup$
    – DarthDonut
    15 hours ago







  • 2




    $begingroup$
    @Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
    $endgroup$
    – DarthDonut
    15 hours ago






  • 2




    $begingroup$
    Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
    $endgroup$
    – AlexP
    15 hours ago







  • 1




    $begingroup$
    @AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
    $endgroup$
    – Ville Niemi
    15 hours ago
















10












$begingroup$


Imagine that humanity builds mining facilities on the moon. We know that the moon has Helium-3 which could be used as fuel for fusion reactors. Also, there are a lot of other resources which could be used for building ships and buildings instead of transporting them from Earth.



Thousands of tons of metals will be mined from the moon in order to sustain a giant fleet of military, civilian and scientific ships for further colonization of our Solar System.



Because all of these actions, the moon will start to lose its own mass. Would this have some kind of impact on its orbit? If it is, how severe would the changes be?










share|improve this question











$endgroup$


This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.









  • 7




    $begingroup$
    Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
    $endgroup$
    – Erik
    16 hours ago










  • $begingroup$
    I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
    $endgroup$
    – DarthDonut
    15 hours ago







  • 2




    $begingroup$
    @Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
    $endgroup$
    – DarthDonut
    15 hours ago






  • 2




    $begingroup$
    Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
    $endgroup$
    – AlexP
    15 hours ago







  • 1




    $begingroup$
    @AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
    $endgroup$
    – Ville Niemi
    15 hours ago














10












10








10


1



$begingroup$


Imagine that humanity builds mining facilities on the moon. We know that the moon has Helium-3 which could be used as fuel for fusion reactors. Also, there are a lot of other resources which could be used for building ships and buildings instead of transporting them from Earth.



Thousands of tons of metals will be mined from the moon in order to sustain a giant fleet of military, civilian and scientific ships for further colonization of our Solar System.



Because all of these actions, the moon will start to lose its own mass. Would this have some kind of impact on its orbit? If it is, how severe would the changes be?










share|improve this question











$endgroup$




Imagine that humanity builds mining facilities on the moon. We know that the moon has Helium-3 which could be used as fuel for fusion reactors. Also, there are a lot of other resources which could be used for building ships and buildings instead of transporting them from Earth.



Thousands of tons of metals will be mined from the moon in order to sustain a giant fleet of military, civilian and scientific ships for further colonization of our Solar System.



Because all of these actions, the moon will start to lose its own mass. Would this have some kind of impact on its orbit? If it is, how severe would the changes be?







physics hard-science moons astronomy natural-resources






share|improve this question















share|improve this question













share|improve this question




share|improve this question








edited 5 hours ago









jdunlop

7,97811846




7,97811846










asked 16 hours ago









Mr.DMr.D

20016




20016



This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.




This question asks for hard science. All answers to this question should be backed up by equations, empirical evidence, scientific papers, other citations, etc. Answers that do not satisfy this requirement might be removed. See the tag description for more information.








  • 7




    $begingroup$
    Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
    $endgroup$
    – Erik
    16 hours ago










  • $begingroup$
    I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
    $endgroup$
    – DarthDonut
    15 hours ago







  • 2




    $begingroup$
    @Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
    $endgroup$
    – DarthDonut
    15 hours ago






  • 2




    $begingroup$
    Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
    $endgroup$
    – AlexP
    15 hours ago







  • 1




    $begingroup$
    @AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
    $endgroup$
    – Ville Niemi
    15 hours ago













  • 7




    $begingroup$
    Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
    $endgroup$
    – Erik
    16 hours ago










  • $begingroup$
    I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
    $endgroup$
    – DarthDonut
    15 hours ago







  • 2




    $begingroup$
    @Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
    $endgroup$
    – DarthDonut
    15 hours ago






  • 2




    $begingroup$
    Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
    $endgroup$
    – AlexP
    15 hours ago







  • 1




    $begingroup$
    @AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
    $endgroup$
    – Ville Niemi
    15 hours ago








7




7




$begingroup$
Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
$endgroup$
– Erik
16 hours ago




$begingroup$
Thousands of tons... that's like "does the gravitational pull on a spoon of sugar change if I remove one grain?". Try something like 10% of the moons mass.
$endgroup$
– Erik
16 hours ago












$begingroup$
I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
$endgroup$
– DarthDonut
15 hours ago





$begingroup$
I have to agree with @Erik . Thousands of tons are not even noticable in comparison to the mass of the moon, which is about 7,349*10^19 tons. The factor difference is about 10^16. Sadly, I cannot calculate everything, hence no answer and just a comment.
$endgroup$
– DarthDonut
15 hours ago





2




2




$begingroup$
@Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
$endgroup$
– DarthDonut
15 hours ago




$begingroup$
@Mr.D That sounds like whoever wants to calculate the effects will have to integrate over time... That poor soul.
$endgroup$
– DarthDonut
15 hours ago




2




2




$begingroup$
Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
$endgroup$
– AlexP
15 hours ago





$begingroup$
Bringing stuff from the Moon to the Earth may change the Moon's orbit, depending on how it's done. No, the changes will not be measurable unless we somehow develop the ability to move vastly larger quantities of stuff. To give you an example, the total worldwide extraction of iron ore is about 2.4 million tonnes per year; this is about one thirtieth of one thousandth of one billionth part of the mass of the Moon. Shifting our entire iron ore extraction from the Earth to the Moon, and keeping at it for one billion years, would extract one thirtieth of one thousandth of the mass of the Moon.
$endgroup$
– AlexP
15 hours ago





1




1




$begingroup$
@AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
$endgroup$
– Ville Niemi
15 hours ago





$begingroup$
@AlexP And you'd be transporting much of it to Earth so the gravity between the two wouldn't really change. I am guessing the biggest effect would actually come from launching and landing the stuff causing "recoil". Although, now that I think of it "big" might not be the correct root word to use.
$endgroup$
– Ville Niemi
15 hours ago











5 Answers
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The mass of the Moon is 7.342×1022 kg.
One ton is 103 kg. How much is thousands of tons? Let's say you have thousands of thousands of tons. That's one million tons, or 109 kg. This is still ten thousands times a billion less than the mass of the moon.



enter image description here



(source: Diego Delso)



Just as a comparison, one of the largest mines that ever operated on Earth, Chuquicamata in Chile, produced much more than "thousands of tons":




...it remains the mine with by far the largest total production of approximately 29 million tonnes of copper to the end of 2007...




And even though it's a big hole in the ground, it is completely negligible relative to the mass of the Earth (or the Moon for that matter).



To answer your question:




Does mining huge amounts of resources on Moon will change its orbit?




The answer is no.



EDIT - the below is wrong because I don't know physics as much as I thought



Let's assume you mined 100 Chuquicamatas on the Moon and removed this mass to build your colonisation fleet. Let's ignore effects of momentum and potential energies etc. The orbit velocity is defined by $v=sqrtGM/r$, where $M$ is the mass. Assuming constant orbit, the new velocity is defined by $v' = sqrtM_0 / M_1$.



Let's plug in some numbers:



$v' = sqrtfrac7.342×10^227.342×10^22 - 100times26×10^6 = 1.0000000000000178$



The Moon's orbit is going to be 1.0000000000000178 times faster.



EDIT - so let's change it a bit.



Since $M$ in the equation $v=sqrtGM/r$ is the mass of Earth, the mass of the Moon means nothing. Then the velocity to radius ratio is fixed regardless. It will not change a thing!



However, we can still calculate the mass change percentage. It will be:



$frac7.342×10^22 - 100times26×10^67.342×10^22 = 0.99999999999996458$



The Moon's new mass will be 99.999999999996458% of the Moon's old mass. Completely meaningless.




Just as an aside, it is often talked about mining asteroids, moons, and all kinds of other extraterrestrial bodies. For example, as you said, the Moon has plenty of helium-3. Asteroids have plenty of precious metals like platinum or iridium. But this is pointless, because you know what place has even more helium, platinum, and iridium? Earth. Earth has much more. And it's easier to mine because you don't need to build spaceships and facilities in hostile environments to do it.



EDIT 2 - space mining



Some comments mentioned that getting things out of the Moon is easier than it is on Earth, and that you can dump things on the Moon without environmental impact. It doesn't work like this.



In films and video games you "mine a resource" (e.g. iridium) from a planetary body. In real life, you build the mining facilities, you build the refining and smelting facilities, you need people to do it, even if you have robots you need people to fix the robots, you need to feed the people, entertain the people, you need a constant supply of consumables to refine the stuff. And this is only the "resource". You don't build spaceships out of helium. You build them out of steel/aluminium/carbon-composites. So you need to mine that as well, and you need to smelt that as well. You also need to build everything on the Moon because otherwise you need to transport all your resources to another place, so you need factories. To do all of that, you are going to need quite a lot of population. And then the environmental factor becomes important. Your mining will generate huge amounts of dust (combination of dryness and low gravity). This just doesn't work.






share|improve this answer











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  • 10




    $begingroup$
    Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
    $endgroup$
    – sp2danny
    11 hours ago






  • 4




    $begingroup$
    Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
    $endgroup$
    – Dave Sherohman
    10 hours ago










  • $begingroup$
    It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
    $endgroup$
    – jdunlop
    7 hours ago










  • $begingroup$
    @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
    $endgroup$
    – Gimelist
    7 hours ago










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    I'm unclear why robots aren't fixing the robots. Can you clarify?
    $endgroup$
    – Yakk
    6 hours ago


















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In order to change the Moon's orbit, you'd have to change its velocity.



You could mine away half its mass without significantly changing its velocity, as long as all the mass was lifted off by something like rockets. If you use mass drivers, and they all throw the same direction, you'd start to see detectable changes in the Moon's orbit by the time you'd thrown a couple million tons (a tiny fraction of one percent of the Moon's mass, but thrown at Lunar escape velocity).



If you use mass drivers that throw in different directions (perhaps you're sending the product all over the Solar System, rather than all to Earth or LEO), once again, the average impulse could be adjusted to zero, keeping the Moon (the part you haven't thrown into space, at least) right where you found it.






share|improve this answer









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  • $begingroup$
    Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
    $endgroup$
    – Pelinore
    11 hours ago











  • $begingroup$
    I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
    $endgroup$
    – Zeiss Ikon
    10 hours ago










  • $begingroup$
    You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
    $endgroup$
    – Nuclear Wang
    8 hours ago











  • $begingroup$
    @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
    $endgroup$
    – Zeiss Ikon
    7 hours ago










  • $begingroup$
    @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
    $endgroup$
    – TheLuckless
    4 hours ago


















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$begingroup$

Simply removing mass from an orbiting body doesn't change its orbit. The orbital radius is given by the velocity and the gravitational pull of the primary (in this case, Earth). The mass of the orbiting body cancels out in the equation and is not relevant.



To see a concrete example, what happens when an astronaut makes a spacewalk from the ISS? Nothing - the astronaut and the ISS continue to follow the same orbital path, even though the ISS is hundreds of times more massive than the astronaut.



As others have touched upon, the process of removing vast amounts of mass might have an effect, depending on how it's done:



  • If you use chemical rockets, for instance, the reaction to the rocket thrust at take-off would have some effect eventually.

  • An electric rail gun launcher (as imagined by Arthur C. Clarke) would transmit the acceleration force through its structure to the Moon and so deliver a torque.

  • a space elevator would have no direct effect.

But these are outwith the scope of the question.






share|improve this answer









$endgroup$








  • 1




    $begingroup$
    The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
    $endgroup$
    – Nuclear Wang
    8 hours ago


















1












$begingroup$

No



Mining on reasonable scales, in the sense you are used to thinking about, won't have any impact on planetary motion.



Yes



If we assume a civilization bewteen K1 and K2, you start having the energy budget to do things like dismantle moons.



The asteroid belt weighs 10^21 kg or so. The non-Titan moons of Saturn, and smaller Jupiter moons, have a few asteroid belt's worth of mass. After that comes Luna.



With a fully automated space mining economy (where robots build robots and mine and refine and recurse and space ships), dismantling low-gravity structures is far easier than ones where you have to go down a gravity well.



So a space faring civilization might start with asteroid tugs pulling asteroids to a central processing asteroid, build more solar panels for energy and smelt more metal for raw materials, and recurse.



As this can proceed exponentially, after a modest period of time you'll be running out of asteroids. The next targets would be building beanstalks on Saturns' (non-Titan) moons, and the other "small" moons of the solar system, and dismantling them for more raw materials. The material from this would then permit building beanstalks on the larger moons.



Before you reach the terrestrial planets you'll get through dismantling Luna, the Galilean moons, Titan, and the sub-planets like Pluto and other post-Neptune bodies.



After that, Mercury, Mars and Venus.



At this point you'll have a choice; if Earth is still important enough, you'll have to skip up to using the Gas Giants for raw material.



This kind of progression is plausible in hard science fiction, and it is a path to get from a K1 level civilization towards a K2 civilization (with Dyson Sphere's or Swarms to harvest the Sun's energy output efficiently).



The dismantling of the moons could alter their orbits; but the energy budgets involved in actually dismantling a planet is so large that the problem of "orbit is being altered" is a trivial one; the orbits alter if they care, and they move in the direction they want them to move.



A K2 civilization has 10^26 Watts of power. The Moon has a Binding Energy of 10^29 J. So a K2 civilization could dismantle the moon in 1000s of seconds; however, a K1 civilization would require 10^13 seconds, or 7 million years.



Hence this plan; the matter from smaller celestial bodies is used to harvest more and more of the sun's energy. At K1.3 taking apart the moon takes 10 thousand years. At K1.5 dismantling the moon takes less than a century. At K1.7 it is a year-scale project. At K1.9 it takes days. At K2.0 it takes hours.



The efficiency of turning matter into solar energy capture and the efficiency of mining the material (which includes lifting it from the gravity well) determine how fast you exponentially climb the Kardashev scale.



TL;DR



Climing the Kardashev by dismantling stellar bodies is "reasonable" path forward. And it could involve mining the moon for raw materials to the point where the moon isn't there anymore.



But barring that level of civilization, no, mining isn't going to mess with orbital mechanics.






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$endgroup$




















    0












    $begingroup$

    This is what one ton of iron looks like. "Thousands of tons" is maybe a couple of full trucks.



    (This should really be a comment, but I just registered.)






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      5 Answers
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      active

      oldest

      votes








      5 Answers
      5






      active

      oldest

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      active

      oldest

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      active

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      23












      $begingroup$

      The mass of the Moon is 7.342×1022 kg.
      One ton is 103 kg. How much is thousands of tons? Let's say you have thousands of thousands of tons. That's one million tons, or 109 kg. This is still ten thousands times a billion less than the mass of the moon.



      enter image description here



      (source: Diego Delso)



      Just as a comparison, one of the largest mines that ever operated on Earth, Chuquicamata in Chile, produced much more than "thousands of tons":




      ...it remains the mine with by far the largest total production of approximately 29 million tonnes of copper to the end of 2007...




      And even though it's a big hole in the ground, it is completely negligible relative to the mass of the Earth (or the Moon for that matter).



      To answer your question:




      Does mining huge amounts of resources on Moon will change its orbit?




      The answer is no.



      EDIT - the below is wrong because I don't know physics as much as I thought



      Let's assume you mined 100 Chuquicamatas on the Moon and removed this mass to build your colonisation fleet. Let's ignore effects of momentum and potential energies etc. The orbit velocity is defined by $v=sqrtGM/r$, where $M$ is the mass. Assuming constant orbit, the new velocity is defined by $v' = sqrtM_0 / M_1$.



      Let's plug in some numbers:



      $v' = sqrtfrac7.342×10^227.342×10^22 - 100times26×10^6 = 1.0000000000000178$



      The Moon's orbit is going to be 1.0000000000000178 times faster.



      EDIT - so let's change it a bit.



      Since $M$ in the equation $v=sqrtGM/r$ is the mass of Earth, the mass of the Moon means nothing. Then the velocity to radius ratio is fixed regardless. It will not change a thing!



      However, we can still calculate the mass change percentage. It will be:



      $frac7.342×10^22 - 100times26×10^67.342×10^22 = 0.99999999999996458$



      The Moon's new mass will be 99.999999999996458% of the Moon's old mass. Completely meaningless.




      Just as an aside, it is often talked about mining asteroids, moons, and all kinds of other extraterrestrial bodies. For example, as you said, the Moon has plenty of helium-3. Asteroids have plenty of precious metals like platinum or iridium. But this is pointless, because you know what place has even more helium, platinum, and iridium? Earth. Earth has much more. And it's easier to mine because you don't need to build spaceships and facilities in hostile environments to do it.



      EDIT 2 - space mining



      Some comments mentioned that getting things out of the Moon is easier than it is on Earth, and that you can dump things on the Moon without environmental impact. It doesn't work like this.



      In films and video games you "mine a resource" (e.g. iridium) from a planetary body. In real life, you build the mining facilities, you build the refining and smelting facilities, you need people to do it, even if you have robots you need people to fix the robots, you need to feed the people, entertain the people, you need a constant supply of consumables to refine the stuff. And this is only the "resource". You don't build spaceships out of helium. You build them out of steel/aluminium/carbon-composites. So you need to mine that as well, and you need to smelt that as well. You also need to build everything on the Moon because otherwise you need to transport all your resources to another place, so you need factories. To do all of that, you are going to need quite a lot of population. And then the environmental factor becomes important. Your mining will generate huge amounts of dust (combination of dryness and low gravity). This just doesn't work.






      share|improve this answer











      $endgroup$








      • 10




        $begingroup$
        Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
        $endgroup$
        – sp2danny
        11 hours ago






      • 4




        $begingroup$
        Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
        $endgroup$
        – Dave Sherohman
        10 hours ago










      • $begingroup$
        It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
        $endgroup$
        – jdunlop
        7 hours ago










      • $begingroup$
        @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
        $endgroup$
        – Gimelist
        7 hours ago










      • $begingroup$
        I'm unclear why robots aren't fixing the robots. Can you clarify?
        $endgroup$
        – Yakk
        6 hours ago















      23












      $begingroup$

      The mass of the Moon is 7.342×1022 kg.
      One ton is 103 kg. How much is thousands of tons? Let's say you have thousands of thousands of tons. That's one million tons, or 109 kg. This is still ten thousands times a billion less than the mass of the moon.



      enter image description here



      (source: Diego Delso)



      Just as a comparison, one of the largest mines that ever operated on Earth, Chuquicamata in Chile, produced much more than "thousands of tons":




      ...it remains the mine with by far the largest total production of approximately 29 million tonnes of copper to the end of 2007...




      And even though it's a big hole in the ground, it is completely negligible relative to the mass of the Earth (or the Moon for that matter).



      To answer your question:




      Does mining huge amounts of resources on Moon will change its orbit?




      The answer is no.



      EDIT - the below is wrong because I don't know physics as much as I thought



      Let's assume you mined 100 Chuquicamatas on the Moon and removed this mass to build your colonisation fleet. Let's ignore effects of momentum and potential energies etc. The orbit velocity is defined by $v=sqrtGM/r$, where $M$ is the mass. Assuming constant orbit, the new velocity is defined by $v' = sqrtM_0 / M_1$.



      Let's plug in some numbers:



      $v' = sqrtfrac7.342×10^227.342×10^22 - 100times26×10^6 = 1.0000000000000178$



      The Moon's orbit is going to be 1.0000000000000178 times faster.



      EDIT - so let's change it a bit.



      Since $M$ in the equation $v=sqrtGM/r$ is the mass of Earth, the mass of the Moon means nothing. Then the velocity to radius ratio is fixed regardless. It will not change a thing!



      However, we can still calculate the mass change percentage. It will be:



      $frac7.342×10^22 - 100times26×10^67.342×10^22 = 0.99999999999996458$



      The Moon's new mass will be 99.999999999996458% of the Moon's old mass. Completely meaningless.




      Just as an aside, it is often talked about mining asteroids, moons, and all kinds of other extraterrestrial bodies. For example, as you said, the Moon has plenty of helium-3. Asteroids have plenty of precious metals like platinum or iridium. But this is pointless, because you know what place has even more helium, platinum, and iridium? Earth. Earth has much more. And it's easier to mine because you don't need to build spaceships and facilities in hostile environments to do it.



      EDIT 2 - space mining



      Some comments mentioned that getting things out of the Moon is easier than it is on Earth, and that you can dump things on the Moon without environmental impact. It doesn't work like this.



      In films and video games you "mine a resource" (e.g. iridium) from a planetary body. In real life, you build the mining facilities, you build the refining and smelting facilities, you need people to do it, even if you have robots you need people to fix the robots, you need to feed the people, entertain the people, you need a constant supply of consumables to refine the stuff. And this is only the "resource". You don't build spaceships out of helium. You build them out of steel/aluminium/carbon-composites. So you need to mine that as well, and you need to smelt that as well. You also need to build everything on the Moon because otherwise you need to transport all your resources to another place, so you need factories. To do all of that, you are going to need quite a lot of population. And then the environmental factor becomes important. Your mining will generate huge amounts of dust (combination of dryness and low gravity). This just doesn't work.






      share|improve this answer











      $endgroup$








      • 10




        $begingroup$
        Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
        $endgroup$
        – sp2danny
        11 hours ago






      • 4




        $begingroup$
        Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
        $endgroup$
        – Dave Sherohman
        10 hours ago










      • $begingroup$
        It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
        $endgroup$
        – jdunlop
        7 hours ago










      • $begingroup$
        @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
        $endgroup$
        – Gimelist
        7 hours ago










      • $begingroup$
        I'm unclear why robots aren't fixing the robots. Can you clarify?
        $endgroup$
        – Yakk
        6 hours ago













      23












      23








      23





      $begingroup$

      The mass of the Moon is 7.342×1022 kg.
      One ton is 103 kg. How much is thousands of tons? Let's say you have thousands of thousands of tons. That's one million tons, or 109 kg. This is still ten thousands times a billion less than the mass of the moon.



      enter image description here



      (source: Diego Delso)



      Just as a comparison, one of the largest mines that ever operated on Earth, Chuquicamata in Chile, produced much more than "thousands of tons":




      ...it remains the mine with by far the largest total production of approximately 29 million tonnes of copper to the end of 2007...




      And even though it's a big hole in the ground, it is completely negligible relative to the mass of the Earth (or the Moon for that matter).



      To answer your question:




      Does mining huge amounts of resources on Moon will change its orbit?




      The answer is no.



      EDIT - the below is wrong because I don't know physics as much as I thought



      Let's assume you mined 100 Chuquicamatas on the Moon and removed this mass to build your colonisation fleet. Let's ignore effects of momentum and potential energies etc. The orbit velocity is defined by $v=sqrtGM/r$, where $M$ is the mass. Assuming constant orbit, the new velocity is defined by $v' = sqrtM_0 / M_1$.



      Let's plug in some numbers:



      $v' = sqrtfrac7.342×10^227.342×10^22 - 100times26×10^6 = 1.0000000000000178$



      The Moon's orbit is going to be 1.0000000000000178 times faster.



      EDIT - so let's change it a bit.



      Since $M$ in the equation $v=sqrtGM/r$ is the mass of Earth, the mass of the Moon means nothing. Then the velocity to radius ratio is fixed regardless. It will not change a thing!



      However, we can still calculate the mass change percentage. It will be:



      $frac7.342×10^22 - 100times26×10^67.342×10^22 = 0.99999999999996458$



      The Moon's new mass will be 99.999999999996458% of the Moon's old mass. Completely meaningless.




      Just as an aside, it is often talked about mining asteroids, moons, and all kinds of other extraterrestrial bodies. For example, as you said, the Moon has plenty of helium-3. Asteroids have plenty of precious metals like platinum or iridium. But this is pointless, because you know what place has even more helium, platinum, and iridium? Earth. Earth has much more. And it's easier to mine because you don't need to build spaceships and facilities in hostile environments to do it.



      EDIT 2 - space mining



      Some comments mentioned that getting things out of the Moon is easier than it is on Earth, and that you can dump things on the Moon without environmental impact. It doesn't work like this.



      In films and video games you "mine a resource" (e.g. iridium) from a planetary body. In real life, you build the mining facilities, you build the refining and smelting facilities, you need people to do it, even if you have robots you need people to fix the robots, you need to feed the people, entertain the people, you need a constant supply of consumables to refine the stuff. And this is only the "resource". You don't build spaceships out of helium. You build them out of steel/aluminium/carbon-composites. So you need to mine that as well, and you need to smelt that as well. You also need to build everything on the Moon because otherwise you need to transport all your resources to another place, so you need factories. To do all of that, you are going to need quite a lot of population. And then the environmental factor becomes important. Your mining will generate huge amounts of dust (combination of dryness and low gravity). This just doesn't work.






      share|improve this answer











      $endgroup$



      The mass of the Moon is 7.342×1022 kg.
      One ton is 103 kg. How much is thousands of tons? Let's say you have thousands of thousands of tons. That's one million tons, or 109 kg. This is still ten thousands times a billion less than the mass of the moon.



      enter image description here



      (source: Diego Delso)



      Just as a comparison, one of the largest mines that ever operated on Earth, Chuquicamata in Chile, produced much more than "thousands of tons":




      ...it remains the mine with by far the largest total production of approximately 29 million tonnes of copper to the end of 2007...




      And even though it's a big hole in the ground, it is completely negligible relative to the mass of the Earth (or the Moon for that matter).



      To answer your question:




      Does mining huge amounts of resources on Moon will change its orbit?




      The answer is no.



      EDIT - the below is wrong because I don't know physics as much as I thought



      Let's assume you mined 100 Chuquicamatas on the Moon and removed this mass to build your colonisation fleet. Let's ignore effects of momentum and potential energies etc. The orbit velocity is defined by $v=sqrtGM/r$, where $M$ is the mass. Assuming constant orbit, the new velocity is defined by $v' = sqrtM_0 / M_1$.



      Let's plug in some numbers:



      $v' = sqrtfrac7.342×10^227.342×10^22 - 100times26×10^6 = 1.0000000000000178$



      The Moon's orbit is going to be 1.0000000000000178 times faster.



      EDIT - so let's change it a bit.



      Since $M$ in the equation $v=sqrtGM/r$ is the mass of Earth, the mass of the Moon means nothing. Then the velocity to radius ratio is fixed regardless. It will not change a thing!



      However, we can still calculate the mass change percentage. It will be:



      $frac7.342×10^22 - 100times26×10^67.342×10^22 = 0.99999999999996458$



      The Moon's new mass will be 99.999999999996458% of the Moon's old mass. Completely meaningless.




      Just as an aside, it is often talked about mining asteroids, moons, and all kinds of other extraterrestrial bodies. For example, as you said, the Moon has plenty of helium-3. Asteroids have plenty of precious metals like platinum or iridium. But this is pointless, because you know what place has even more helium, platinum, and iridium? Earth. Earth has much more. And it's easier to mine because you don't need to build spaceships and facilities in hostile environments to do it.



      EDIT 2 - space mining



      Some comments mentioned that getting things out of the Moon is easier than it is on Earth, and that you can dump things on the Moon without environmental impact. It doesn't work like this.



      In films and video games you "mine a resource" (e.g. iridium) from a planetary body. In real life, you build the mining facilities, you build the refining and smelting facilities, you need people to do it, even if you have robots you need people to fix the robots, you need to feed the people, entertain the people, you need a constant supply of consumables to refine the stuff. And this is only the "resource". You don't build spaceships out of helium. You build them out of steel/aluminium/carbon-composites. So you need to mine that as well, and you need to smelt that as well. You also need to build everything on the Moon because otherwise you need to transport all your resources to another place, so you need factories. To do all of that, you are going to need quite a lot of population. And then the environmental factor becomes important. Your mining will generate huge amounts of dust (combination of dryness and low gravity). This just doesn't work.







      share|improve this answer














      share|improve this answer



      share|improve this answer








      edited 6 hours ago

























      answered 15 hours ago









      GimelistGimelist

      2,549512




      2,549512







      • 10




        $begingroup$
        Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
        $endgroup$
        – sp2danny
        11 hours ago






      • 4




        $begingroup$
        Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
        $endgroup$
        – Dave Sherohman
        10 hours ago










      • $begingroup$
        It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
        $endgroup$
        – jdunlop
        7 hours ago










      • $begingroup$
        @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
        $endgroup$
        – Gimelist
        7 hours ago










      • $begingroup$
        I'm unclear why robots aren't fixing the robots. Can you clarify?
        $endgroup$
        – Yakk
        6 hours ago












      • 10




        $begingroup$
        Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
        $endgroup$
        – sp2danny
        11 hours ago






      • 4




        $begingroup$
        Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
        $endgroup$
        – Dave Sherohman
        10 hours ago










      • $begingroup$
        It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
        $endgroup$
        – jdunlop
        7 hours ago










      • $begingroup$
        @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
        $endgroup$
        – Gimelist
        7 hours ago










      • $begingroup$
        I'm unclear why robots aren't fixing the robots. Can you clarify?
        $endgroup$
        – Yakk
        6 hours ago







      10




      10




      $begingroup$
      Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
      $endgroup$
      – sp2danny
      11 hours ago




      $begingroup$
      Regarding your last paragraph; Mining the materials on earth, under the assumption that the final destination is not on earth, means that you trigger the tyranny of the rocket equation. Furthermore, most of the resources are on not earth. You can collect a billion times more solar power than on earth, for example.
      $endgroup$
      – sp2danny
      11 hours ago




      4




      4




      $begingroup$
      Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
      $endgroup$
      – Dave Sherohman
      10 hours ago




      $begingroup$
      Your equation is wrong. Or, rather, you're applying it incorrectly. M is the mass of the primary (Earth), not the mass of the satellite (the moon). If you put a one-ton mass and a 10,000-ton mass into orbit beside the (419-ton) ISS, they'll all orbit at the same velocity.
      $endgroup$
      – Dave Sherohman
      10 hours ago












      $begingroup$
      It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
      $endgroup$
      – jdunlop
      7 hours ago




      $begingroup$
      It's also worth noting that you can mine a megaton of iridium (or whatever other mineral suits your fancy) from the moon, or an asteroid, and just dump the spoilage wherever you want, effectively. No environmental protection laws, no rivers to poison, no species to squash. Assuming getting to space is made cheap by some means, there's a lot to recommend resource extraction up there.
      $endgroup$
      – jdunlop
      7 hours ago












      $begingroup$
      @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
      $endgroup$
      – Gimelist
      7 hours ago




      $begingroup$
      @DaveSherohman this is what happens when you give a physics problem to a geologist, right? Then it’s even better. The orbit will not change at all.
      $endgroup$
      – Gimelist
      7 hours ago












      $begingroup$
      I'm unclear why robots aren't fixing the robots. Can you clarify?
      $endgroup$
      – Yakk
      6 hours ago




      $begingroup$
      I'm unclear why robots aren't fixing the robots. Can you clarify?
      $endgroup$
      – Yakk
      6 hours ago











      12












      $begingroup$

      In order to change the Moon's orbit, you'd have to change its velocity.



      You could mine away half its mass without significantly changing its velocity, as long as all the mass was lifted off by something like rockets. If you use mass drivers, and they all throw the same direction, you'd start to see detectable changes in the Moon's orbit by the time you'd thrown a couple million tons (a tiny fraction of one percent of the Moon's mass, but thrown at Lunar escape velocity).



      If you use mass drivers that throw in different directions (perhaps you're sending the product all over the Solar System, rather than all to Earth or LEO), once again, the average impulse could be adjusted to zero, keeping the Moon (the part you haven't thrown into space, at least) right where you found it.






      share|improve this answer









      $endgroup$












      • $begingroup$
        Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
        $endgroup$
        – Pelinore
        11 hours ago











      • $begingroup$
        I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
        $endgroup$
        – Zeiss Ikon
        10 hours ago










      • $begingroup$
        You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
        $endgroup$
        – Nuclear Wang
        8 hours ago











      • $begingroup$
        @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
        $endgroup$
        – Zeiss Ikon
        7 hours ago










      • $begingroup$
        @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
        $endgroup$
        – TheLuckless
        4 hours ago















      12












      $begingroup$

      In order to change the Moon's orbit, you'd have to change its velocity.



      You could mine away half its mass without significantly changing its velocity, as long as all the mass was lifted off by something like rockets. If you use mass drivers, and they all throw the same direction, you'd start to see detectable changes in the Moon's orbit by the time you'd thrown a couple million tons (a tiny fraction of one percent of the Moon's mass, but thrown at Lunar escape velocity).



      If you use mass drivers that throw in different directions (perhaps you're sending the product all over the Solar System, rather than all to Earth or LEO), once again, the average impulse could be adjusted to zero, keeping the Moon (the part you haven't thrown into space, at least) right where you found it.






      share|improve this answer









      $endgroup$












      • $begingroup$
        Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
        $endgroup$
        – Pelinore
        11 hours ago











      • $begingroup$
        I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
        $endgroup$
        – Zeiss Ikon
        10 hours ago










      • $begingroup$
        You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
        $endgroup$
        – Nuclear Wang
        8 hours ago











      • $begingroup$
        @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
        $endgroup$
        – Zeiss Ikon
        7 hours ago










      • $begingroup$
        @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
        $endgroup$
        – TheLuckless
        4 hours ago













      12












      12








      12





      $begingroup$

      In order to change the Moon's orbit, you'd have to change its velocity.



      You could mine away half its mass without significantly changing its velocity, as long as all the mass was lifted off by something like rockets. If you use mass drivers, and they all throw the same direction, you'd start to see detectable changes in the Moon's orbit by the time you'd thrown a couple million tons (a tiny fraction of one percent of the Moon's mass, but thrown at Lunar escape velocity).



      If you use mass drivers that throw in different directions (perhaps you're sending the product all over the Solar System, rather than all to Earth or LEO), once again, the average impulse could be adjusted to zero, keeping the Moon (the part you haven't thrown into space, at least) right where you found it.






      share|improve this answer









      $endgroup$



      In order to change the Moon's orbit, you'd have to change its velocity.



      You could mine away half its mass without significantly changing its velocity, as long as all the mass was lifted off by something like rockets. If you use mass drivers, and they all throw the same direction, you'd start to see detectable changes in the Moon's orbit by the time you'd thrown a couple million tons (a tiny fraction of one percent of the Moon's mass, but thrown at Lunar escape velocity).



      If you use mass drivers that throw in different directions (perhaps you're sending the product all over the Solar System, rather than all to Earth or LEO), once again, the average impulse could be adjusted to zero, keeping the Moon (the part you haven't thrown into space, at least) right where you found it.







      share|improve this answer












      share|improve this answer



      share|improve this answer










      answered 11 hours ago









      Zeiss IkonZeiss Ikon

      1,811115




      1,811115











      • $begingroup$
        Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
        $endgroup$
        – Pelinore
        11 hours ago











      • $begingroup$
        I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
        $endgroup$
        – Zeiss Ikon
        10 hours ago










      • $begingroup$
        You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
        $endgroup$
        – Nuclear Wang
        8 hours ago











      • $begingroup$
        @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
        $endgroup$
        – Zeiss Ikon
        7 hours ago










      • $begingroup$
        @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
        $endgroup$
        – TheLuckless
        4 hours ago
















      • $begingroup$
        Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
        $endgroup$
        – Pelinore
        11 hours ago











      • $begingroup$
        I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
        $endgroup$
        – Zeiss Ikon
        10 hours ago










      • $begingroup$
        You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
        $endgroup$
        – Nuclear Wang
        8 hours ago











      • $begingroup$
        @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
        $endgroup$
        – Zeiss Ikon
        7 hours ago










      • $begingroup$
        @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
        $endgroup$
        – TheLuckless
        4 hours ago















      $begingroup$
      Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
      $endgroup$
      – Pelinore
      11 hours ago





      $begingroup$
      Now that's nice observation, it has a hard science tag though so have you any links or math for us? I probably shouldn't (because, tags) but [+] anyway.
      $endgroup$
      – Pelinore
      11 hours ago













      $begingroup$
      I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
      $endgroup$
      – Zeiss Ikon
      10 hours ago




      $begingroup$
      I'll try to come back later, when I have time to dig them up, and link the rocket equation, Lunar escape velocity, etc.
      $endgroup$
      – Zeiss Ikon
      10 hours ago












      $begingroup$
      You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
      $endgroup$
      – Nuclear Wang
      8 hours ago





      $begingroup$
      You are neglecting the fact that as mass is removed from the moon, the orbital radius increases because the barycenter moves toward the center of the earth. A massless moon has a ~1% higher orbital radius and a ~1% slower orbit. It may maintain the same speed, but will have a longer orbital path.
      $endgroup$
      – Nuclear Wang
      8 hours ago













      $begingroup$
      @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
      $endgroup$
      – Zeiss Ikon
      7 hours ago




      $begingroup$
      @NuclearWang While that's correct, unless you're going to remove enough mass to see the mines with the naked eye from Earth, and do it pretty asymmetrically, only physicists will be able to tell the orbit has changed (by bouncing lasers off those reflectors Apollo left behind). Don't forget, the Moon is moving away from Earth by something like an inch a year, just from tidal forces.
      $endgroup$
      – Zeiss Ikon
      7 hours ago












      $begingroup$
      @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
      $endgroup$
      – TheLuckless
      4 hours ago




      $begingroup$
      @ZeissIkon wouldn't those tidal forces be important to factor in if doing a complete overview of end to end effects as larger portions of mass are removed? ie: What is the long term impact between the earth-moon system's tidal forces as with ship greater percentages of the moon out of the system, or spread it around a larger orbit?
      $endgroup$
      – TheLuckless
      4 hours ago











      6












      $begingroup$

      Simply removing mass from an orbiting body doesn't change its orbit. The orbital radius is given by the velocity and the gravitational pull of the primary (in this case, Earth). The mass of the orbiting body cancels out in the equation and is not relevant.



      To see a concrete example, what happens when an astronaut makes a spacewalk from the ISS? Nothing - the astronaut and the ISS continue to follow the same orbital path, even though the ISS is hundreds of times more massive than the astronaut.



      As others have touched upon, the process of removing vast amounts of mass might have an effect, depending on how it's done:



      • If you use chemical rockets, for instance, the reaction to the rocket thrust at take-off would have some effect eventually.

      • An electric rail gun launcher (as imagined by Arthur C. Clarke) would transmit the acceleration force through its structure to the Moon and so deliver a torque.

      • a space elevator would have no direct effect.

      But these are outwith the scope of the question.






      share|improve this answer









      $endgroup$








      • 1




        $begingroup$
        The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
        $endgroup$
        – Nuclear Wang
        8 hours ago















      6












      $begingroup$

      Simply removing mass from an orbiting body doesn't change its orbit. The orbital radius is given by the velocity and the gravitational pull of the primary (in this case, Earth). The mass of the orbiting body cancels out in the equation and is not relevant.



      To see a concrete example, what happens when an astronaut makes a spacewalk from the ISS? Nothing - the astronaut and the ISS continue to follow the same orbital path, even though the ISS is hundreds of times more massive than the astronaut.



      As others have touched upon, the process of removing vast amounts of mass might have an effect, depending on how it's done:



      • If you use chemical rockets, for instance, the reaction to the rocket thrust at take-off would have some effect eventually.

      • An electric rail gun launcher (as imagined by Arthur C. Clarke) would transmit the acceleration force through its structure to the Moon and so deliver a torque.

      • a space elevator would have no direct effect.

      But these are outwith the scope of the question.






      share|improve this answer









      $endgroup$








      • 1




        $begingroup$
        The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
        $endgroup$
        – Nuclear Wang
        8 hours ago













      6












      6








      6





      $begingroup$

      Simply removing mass from an orbiting body doesn't change its orbit. The orbital radius is given by the velocity and the gravitational pull of the primary (in this case, Earth). The mass of the orbiting body cancels out in the equation and is not relevant.



      To see a concrete example, what happens when an astronaut makes a spacewalk from the ISS? Nothing - the astronaut and the ISS continue to follow the same orbital path, even though the ISS is hundreds of times more massive than the astronaut.



      As others have touched upon, the process of removing vast amounts of mass might have an effect, depending on how it's done:



      • If you use chemical rockets, for instance, the reaction to the rocket thrust at take-off would have some effect eventually.

      • An electric rail gun launcher (as imagined by Arthur C. Clarke) would transmit the acceleration force through its structure to the Moon and so deliver a torque.

      • a space elevator would have no direct effect.

      But these are outwith the scope of the question.






      share|improve this answer









      $endgroup$



      Simply removing mass from an orbiting body doesn't change its orbit. The orbital radius is given by the velocity and the gravitational pull of the primary (in this case, Earth). The mass of the orbiting body cancels out in the equation and is not relevant.



      To see a concrete example, what happens when an astronaut makes a spacewalk from the ISS? Nothing - the astronaut and the ISS continue to follow the same orbital path, even though the ISS is hundreds of times more massive than the astronaut.



      As others have touched upon, the process of removing vast amounts of mass might have an effect, depending on how it's done:



      • If you use chemical rockets, for instance, the reaction to the rocket thrust at take-off would have some effect eventually.

      • An electric rail gun launcher (as imagined by Arthur C. Clarke) would transmit the acceleration force through its structure to the Moon and so deliver a torque.

      • a space elevator would have no direct effect.

      But these are outwith the scope of the question.







      share|improve this answer












      share|improve this answer



      share|improve this answer










      answered 10 hours ago









      Oscar BravoOscar Bravo

      36816




      36816







      • 1




        $begingroup$
        The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
        $endgroup$
        – Nuclear Wang
        8 hours ago












      • 1




        $begingroup$
        The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
        $endgroup$
        – Nuclear Wang
        8 hours ago







      1




      1




      $begingroup$
      The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
      $endgroup$
      – Nuclear Wang
      8 hours ago




      $begingroup$
      The mass of the satellite is irrelevant only when it's a negligible fraction of the planet's mass, which is not true for the moon. The earth-ISS and earth-astronaut barycenters are in practically the same spot, the earth-moon and earth-"hollow moon" barycenters are thousands of miles apart.
      $endgroup$
      – Nuclear Wang
      8 hours ago











      1












      $begingroup$

      No



      Mining on reasonable scales, in the sense you are used to thinking about, won't have any impact on planetary motion.



      Yes



      If we assume a civilization bewteen K1 and K2, you start having the energy budget to do things like dismantle moons.



      The asteroid belt weighs 10^21 kg or so. The non-Titan moons of Saturn, and smaller Jupiter moons, have a few asteroid belt's worth of mass. After that comes Luna.



      With a fully automated space mining economy (where robots build robots and mine and refine and recurse and space ships), dismantling low-gravity structures is far easier than ones where you have to go down a gravity well.



      So a space faring civilization might start with asteroid tugs pulling asteroids to a central processing asteroid, build more solar panels for energy and smelt more metal for raw materials, and recurse.



      As this can proceed exponentially, after a modest period of time you'll be running out of asteroids. The next targets would be building beanstalks on Saturns' (non-Titan) moons, and the other "small" moons of the solar system, and dismantling them for more raw materials. The material from this would then permit building beanstalks on the larger moons.



      Before you reach the terrestrial planets you'll get through dismantling Luna, the Galilean moons, Titan, and the sub-planets like Pluto and other post-Neptune bodies.



      After that, Mercury, Mars and Venus.



      At this point you'll have a choice; if Earth is still important enough, you'll have to skip up to using the Gas Giants for raw material.



      This kind of progression is plausible in hard science fiction, and it is a path to get from a K1 level civilization towards a K2 civilization (with Dyson Sphere's or Swarms to harvest the Sun's energy output efficiently).



      The dismantling of the moons could alter their orbits; but the energy budgets involved in actually dismantling a planet is so large that the problem of "orbit is being altered" is a trivial one; the orbits alter if they care, and they move in the direction they want them to move.



      A K2 civilization has 10^26 Watts of power. The Moon has a Binding Energy of 10^29 J. So a K2 civilization could dismantle the moon in 1000s of seconds; however, a K1 civilization would require 10^13 seconds, or 7 million years.



      Hence this plan; the matter from smaller celestial bodies is used to harvest more and more of the sun's energy. At K1.3 taking apart the moon takes 10 thousand years. At K1.5 dismantling the moon takes less than a century. At K1.7 it is a year-scale project. At K1.9 it takes days. At K2.0 it takes hours.



      The efficiency of turning matter into solar energy capture and the efficiency of mining the material (which includes lifting it from the gravity well) determine how fast you exponentially climb the Kardashev scale.



      TL;DR



      Climing the Kardashev by dismantling stellar bodies is "reasonable" path forward. And it could involve mining the moon for raw materials to the point where the moon isn't there anymore.



      But barring that level of civilization, no, mining isn't going to mess with orbital mechanics.






      share|improve this answer









      $endgroup$

















        1












        $begingroup$

        No



        Mining on reasonable scales, in the sense you are used to thinking about, won't have any impact on planetary motion.



        Yes



        If we assume a civilization bewteen K1 and K2, you start having the energy budget to do things like dismantle moons.



        The asteroid belt weighs 10^21 kg or so. The non-Titan moons of Saturn, and smaller Jupiter moons, have a few asteroid belt's worth of mass. After that comes Luna.



        With a fully automated space mining economy (where robots build robots and mine and refine and recurse and space ships), dismantling low-gravity structures is far easier than ones where you have to go down a gravity well.



        So a space faring civilization might start with asteroid tugs pulling asteroids to a central processing asteroid, build more solar panels for energy and smelt more metal for raw materials, and recurse.



        As this can proceed exponentially, after a modest period of time you'll be running out of asteroids. The next targets would be building beanstalks on Saturns' (non-Titan) moons, and the other "small" moons of the solar system, and dismantling them for more raw materials. The material from this would then permit building beanstalks on the larger moons.



        Before you reach the terrestrial planets you'll get through dismantling Luna, the Galilean moons, Titan, and the sub-planets like Pluto and other post-Neptune bodies.



        After that, Mercury, Mars and Venus.



        At this point you'll have a choice; if Earth is still important enough, you'll have to skip up to using the Gas Giants for raw material.



        This kind of progression is plausible in hard science fiction, and it is a path to get from a K1 level civilization towards a K2 civilization (with Dyson Sphere's or Swarms to harvest the Sun's energy output efficiently).



        The dismantling of the moons could alter their orbits; but the energy budgets involved in actually dismantling a planet is so large that the problem of "orbit is being altered" is a trivial one; the orbits alter if they care, and they move in the direction they want them to move.



        A K2 civilization has 10^26 Watts of power. The Moon has a Binding Energy of 10^29 J. So a K2 civilization could dismantle the moon in 1000s of seconds; however, a K1 civilization would require 10^13 seconds, or 7 million years.



        Hence this plan; the matter from smaller celestial bodies is used to harvest more and more of the sun's energy. At K1.3 taking apart the moon takes 10 thousand years. At K1.5 dismantling the moon takes less than a century. At K1.7 it is a year-scale project. At K1.9 it takes days. At K2.0 it takes hours.



        The efficiency of turning matter into solar energy capture and the efficiency of mining the material (which includes lifting it from the gravity well) determine how fast you exponentially climb the Kardashev scale.



        TL;DR



        Climing the Kardashev by dismantling stellar bodies is "reasonable" path forward. And it could involve mining the moon for raw materials to the point where the moon isn't there anymore.



        But barring that level of civilization, no, mining isn't going to mess with orbital mechanics.






        share|improve this answer









        $endgroup$















          1












          1








          1





          $begingroup$

          No



          Mining on reasonable scales, in the sense you are used to thinking about, won't have any impact on planetary motion.



          Yes



          If we assume a civilization bewteen K1 and K2, you start having the energy budget to do things like dismantle moons.



          The asteroid belt weighs 10^21 kg or so. The non-Titan moons of Saturn, and smaller Jupiter moons, have a few asteroid belt's worth of mass. After that comes Luna.



          With a fully automated space mining economy (where robots build robots and mine and refine and recurse and space ships), dismantling low-gravity structures is far easier than ones where you have to go down a gravity well.



          So a space faring civilization might start with asteroid tugs pulling asteroids to a central processing asteroid, build more solar panels for energy and smelt more metal for raw materials, and recurse.



          As this can proceed exponentially, after a modest period of time you'll be running out of asteroids. The next targets would be building beanstalks on Saturns' (non-Titan) moons, and the other "small" moons of the solar system, and dismantling them for more raw materials. The material from this would then permit building beanstalks on the larger moons.



          Before you reach the terrestrial planets you'll get through dismantling Luna, the Galilean moons, Titan, and the sub-planets like Pluto and other post-Neptune bodies.



          After that, Mercury, Mars and Venus.



          At this point you'll have a choice; if Earth is still important enough, you'll have to skip up to using the Gas Giants for raw material.



          This kind of progression is plausible in hard science fiction, and it is a path to get from a K1 level civilization towards a K2 civilization (with Dyson Sphere's or Swarms to harvest the Sun's energy output efficiently).



          The dismantling of the moons could alter their orbits; but the energy budgets involved in actually dismantling a planet is so large that the problem of "orbit is being altered" is a trivial one; the orbits alter if they care, and they move in the direction they want them to move.



          A K2 civilization has 10^26 Watts of power. The Moon has a Binding Energy of 10^29 J. So a K2 civilization could dismantle the moon in 1000s of seconds; however, a K1 civilization would require 10^13 seconds, or 7 million years.



          Hence this plan; the matter from smaller celestial bodies is used to harvest more and more of the sun's energy. At K1.3 taking apart the moon takes 10 thousand years. At K1.5 dismantling the moon takes less than a century. At K1.7 it is a year-scale project. At K1.9 it takes days. At K2.0 it takes hours.



          The efficiency of turning matter into solar energy capture and the efficiency of mining the material (which includes lifting it from the gravity well) determine how fast you exponentially climb the Kardashev scale.



          TL;DR



          Climing the Kardashev by dismantling stellar bodies is "reasonable" path forward. And it could involve mining the moon for raw materials to the point where the moon isn't there anymore.



          But barring that level of civilization, no, mining isn't going to mess with orbital mechanics.






          share|improve this answer









          $endgroup$



          No



          Mining on reasonable scales, in the sense you are used to thinking about, won't have any impact on planetary motion.



          Yes



          If we assume a civilization bewteen K1 and K2, you start having the energy budget to do things like dismantle moons.



          The asteroid belt weighs 10^21 kg or so. The non-Titan moons of Saturn, and smaller Jupiter moons, have a few asteroid belt's worth of mass. After that comes Luna.



          With a fully automated space mining economy (where robots build robots and mine and refine and recurse and space ships), dismantling low-gravity structures is far easier than ones where you have to go down a gravity well.



          So a space faring civilization might start with asteroid tugs pulling asteroids to a central processing asteroid, build more solar panels for energy and smelt more metal for raw materials, and recurse.



          As this can proceed exponentially, after a modest period of time you'll be running out of asteroids. The next targets would be building beanstalks on Saturns' (non-Titan) moons, and the other "small" moons of the solar system, and dismantling them for more raw materials. The material from this would then permit building beanstalks on the larger moons.



          Before you reach the terrestrial planets you'll get through dismantling Luna, the Galilean moons, Titan, and the sub-planets like Pluto and other post-Neptune bodies.



          After that, Mercury, Mars and Venus.



          At this point you'll have a choice; if Earth is still important enough, you'll have to skip up to using the Gas Giants for raw material.



          This kind of progression is plausible in hard science fiction, and it is a path to get from a K1 level civilization towards a K2 civilization (with Dyson Sphere's or Swarms to harvest the Sun's energy output efficiently).



          The dismantling of the moons could alter their orbits; but the energy budgets involved in actually dismantling a planet is so large that the problem of "orbit is being altered" is a trivial one; the orbits alter if they care, and they move in the direction they want them to move.



          A K2 civilization has 10^26 Watts of power. The Moon has a Binding Energy of 10^29 J. So a K2 civilization could dismantle the moon in 1000s of seconds; however, a K1 civilization would require 10^13 seconds, or 7 million years.



          Hence this plan; the matter from smaller celestial bodies is used to harvest more and more of the sun's energy. At K1.3 taking apart the moon takes 10 thousand years. At K1.5 dismantling the moon takes less than a century. At K1.7 it is a year-scale project. At K1.9 it takes days. At K2.0 it takes hours.



          The efficiency of turning matter into solar energy capture and the efficiency of mining the material (which includes lifting it from the gravity well) determine how fast you exponentially climb the Kardashev scale.



          TL;DR



          Climing the Kardashev by dismantling stellar bodies is "reasonable" path forward. And it could involve mining the moon for raw materials to the point where the moon isn't there anymore.



          But barring that level of civilization, no, mining isn't going to mess with orbital mechanics.







          share|improve this answer












          share|improve this answer



          share|improve this answer










          answered 5 hours ago









          YakkYakk

          8,90911238




          8,90911238





















              0












              $begingroup$

              This is what one ton of iron looks like. "Thousands of tons" is maybe a couple of full trucks.



              (This should really be a comment, but I just registered.)






              share|improve this answer








              New contributor




              markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
              Check out our Code of Conduct.






              $endgroup$

















                0












                $begingroup$

                This is what one ton of iron looks like. "Thousands of tons" is maybe a couple of full trucks.



                (This should really be a comment, but I just registered.)






                share|improve this answer








                New contributor




                markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                Check out our Code of Conduct.






                $endgroup$















                  0












                  0








                  0





                  $begingroup$

                  This is what one ton of iron looks like. "Thousands of tons" is maybe a couple of full trucks.



                  (This should really be a comment, but I just registered.)






                  share|improve this answer








                  New contributor




                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.






                  $endgroup$



                  This is what one ton of iron looks like. "Thousands of tons" is maybe a couple of full trucks.



                  (This should really be a comment, but I just registered.)







                  share|improve this answer








                  New contributor




                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.









                  share|improve this answer



                  share|improve this answer






                  New contributor




                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.









                  answered 2 hours ago









                  markemusmarkemus

                  1




                  1




                  New contributor




                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.





                  New contributor





                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.






                  markemus is a new contributor to this site. Take care in asking for clarification, commenting, and answering.
                  Check out our Code of Conduct.



























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