This is yet another (most welcome) hypothesis in explaining the sheer differences in our Moon’s nearside and farside. Just last month I wrote a feature article explaining the other leading theories for what caused these nearside-farside differences if anyone’s interested: https://blog.jatan.space/p/the-two-faced-moon
The Moon is so much more interesting than most people think.
I was wondering if a possible explanation is that, due to the gravity attraction of the earth, the hot, heavy, inner part of the moon, which is richer in heavy elements, I guess, like iron is closer to the near-side surface. Since in the far-side the hot, heavy part is too far from the surface the eruption activity is small or non-existing.
Because the moon is tidally locked to the earth the pull always act in the same direction.
I was imagining the moon as a drop of liquid in the vacuum space with a denser core at the center. The heavier core would be at the center because of the moon's own gravity. In the presence of the earth's gravity the denser part of the "liquid drop" will be centered more closely to one side and so the volcanic activity would be strongly biased.
This comment is being downvoted but it's correct. The moon all moves at the same speed, which is the speed at its center of gravity. The face nearest us is moving slightly slower than it should at that distance so it is pulled towards earth. The far side is moving slightly faster, so it is pulled away from the earth.
No, because the moon is tidal-locked to the earth so the pull is always in the same direction. Tidal-locked means the moon always show the same face to the earth.
The effect is more of a stretch along an axis pointing toward and away from the center of mass of the Earth-Moon pair. The result is like a tide that rises in opposing directions.
You're referring to the fictitious centrifugal force [0] which is actually a minor change in inertia—very much out shined by the centripetal force of gravity. For example, on earth if you weigh 200 lbs on the North Pole, you'd weigh about 199lbs on the equator. On the moon, this tiny effect would be wiped out by gravity.
Your example with the North Pole refers to the centrifugal force from the Earth spinning on its axis. But the relevant centrifugal force here is not the one from the Moon spinning on its axis, but rather the one from the Moon orbiting the Earth.
But in any case, you can think about the whole thing without considering centrifugal force. If the Moon wasn't orbiting but rather in freefall towards us, then the Earth would continue to have two tides right up until the moment it hit us.
The point is simply that gravity weakens with distance. So the pull of the Earth on the near side of the Moon is slightly stronger than the pull of the Earth on the Moon's centre. And the Earth's pull on the far side of the Moon is slightly weaker than the pull of the Earth on the Moon's centre. So if we consider the near and far regions of the Moon relative to whatever the Moon is doing on net, it will be as though the near side is being pulled towards the Earth and the far side is being pushed away.
I recently took an old-school "voxel" algorithm and munged some NASA moon terrain data to try to create a game.
I really have enjoyed learning about the Moon's geography just from flying around the terrain, picking locations for "lunar bases" and such. Fascinating cracks and valleys, grooves, a straight mountain range — in general things I was not expecting on a planetoid without water/erosion.
It really is stark how different the far side of the Moon is from the near side. Insanely pock-marked with so many craters.... I assumed there was an Earth component to that in the same way the Earth has locked the Moon into an orbit/rotation that is always facing us.
I'm become very keen to learn more about the Moon now.
For the Moon the (images) data seems to be bucketed with regard to pixels-per-degree (PPD), the more coarse data set being 64ppd data (finer resolution for the Moon goes at least as high as 512ppd that I have found). Sadly, my workflow (image editors, and Blender as you mentioned) are already straining with the 64ppd data-set so I did not try to go higher resolution. It means though that my Moon is wildly small — the lunar bases that seem to be a paltry 7x7 or 9x9 voxels are in fact the size of a small town.
I began with NASA's "CGI Moon Kit" [1] which, as I say, is 64ppd. There is both a "color data" image and an "elevation data" image (where the greyscale value of the image represents elevation). Polar data was garbage (and would look wildly distorted in my tile-based voxel algorithm so I confess that I tossed it — cropped everything outside 60-degrees latitude basically - I just limit fuel in the game to keep pesky kids from trying to get too deep into the polar regions).
Even at 64ppd and poles cropped, I still ended up with two images that were 23040 × 11264 pixels in size. This turned out to be a challenge for most of the image editing apps I have. Blender handled it (but barely).
With both color + elevation images I followed an online tutorial [2] meant for cartographers wanting to use Blender for relief shading. NASA's moon map had no shadows (probably a good thing). I was not going to try to real-time shade/light the voxel terrain so I settled on "burning in" the shadows with Blender. While my MacBook ran some 8 hours or so (over night) to generate the relief-shaded lunar map, the result was quite nice. As a result, it is near sunset everywhere on my Moon, ha ha.
With a relief-shaded image representing the color and a same-sized image representing the elevation, I wrote a custom app to read both files into memory and then generate the correct number of 512 x 512 tiles that contain both the elevation data and RGB data in a single raw file. Now I have 45 x 22 raw tiles covering the entire 64ppd Moon. The voxel algorithm uses simple math to figure out which tile a given voxel is to be found, reads the elevation/color data.
In hindsight, I could have output PNG files or something with alpha channel (where alpha would be interpreted as elevation). As it turned out, the Moon color was so close to greyscale that I ended up treating it as such and used only the green channel when creating my Moon tiles (so the tile data has only a single 8-bit value for elevation and a single 8-bit value for "color" per voxel — cut the raw tile size in half).
Still wrapping up the game [3]. I'll put the sources up on Github end of the month, I think.
I did some cropping of the LOLA dataset to a .raw that Unity3D could understand as terrain input: https://github.com/amb/SplitTIFF ... a couple of years ago
Happy to hear any better alternatives for the task.
I made it to Ptolemaeus depot without crashing! And now Parry. Though it didn't register by landing at Cop, and I then I tried moving over a craft length and I crashed.
Fun game! It would be nice if the altimeter had a high res mode for the last few meters.
I either watch out the window the last bit and watch the base lights to judge the last few meters or I just watch the vertical velocity nixie (numeric display) and feather the throttle to keep Vert V. close to zero — eventually you touch down gently.
Thanks for the feedback. Hopefully I'll get more of that (and likely your request will come up again as well).
Fascinating. Are there upcoming plans from any space agency to improve that 64PPD with upcoming or existing satellites or Earth-based capture of moon topography?
There are 512ppd data sets [1] already. As I say, I found them unwieldy with my workflow. A new workflow would be required to process these into "game tiles".
Whoops. I missed that you mentioned higher PPD is available. If your workflow was improved to accommodate it, I presume it would produce more, for lack of a better phrase, life-like terrain? Would a much higher PPD be required to reach a threshold to improve the experience. And are there plans coming to get finer detail than 512PPD?
Becouse of the orbital lock it’s interesting to think of it like a shield for earth. I imagine a lot of those craters were by asteroids that would have hit earth, esp the perfectly round ones in the center. The oblong ones or ones towards the edges might have come at an angle that wouldn’t have hit earth. Seems like a fascinating way to study earths impact history if we end up exploring the dark side of the moon in more detail.
I believe consensus is that the moon will eventually drift away from the Earth. Do such impacts, predominantly on the far side of the moon, apply enough force to change that prediction? Are such projections of whether the moon leaves Earth orbit (or instead collides with Earth) accounting for this?
The moon is drifting away from Earth at a rate of about four centimeters per year [1]. Inbound impacts on the far side won't significantly affect this because of the way orbital mechanics works. To lower an orbital altitude, you need thrust opposing the orbital vector. (This is why spacecraft orient the way they do, with engines pointing in the direction of travel, for retrofire.) Thrusting toward or away from the orbital center of gravity (in this case Earth) can affect the circularity of the orbit, but that's all. In the case of the moon intercepting an impactor that'd otherwise strike Earth, the thrust vector is necessarily toward Earth, so the effect would be to render the moon's orbit infinitesimally more elliptical, with the increase along the major axis balanced by an equally minimal decrease along the minor axis. (To the extent the force vector of the impact is displaced from the axis through the moon's own center of gravity, that will affect the spin of the moon, but not its orbit.)
According to the linked article, it will take about fifteen billion years for the moon to escape Earth orbit entirely. I haven't checked, but I believe that's considerably longer than it is expected to take for the Sun to expand as a red giant and render Earth uninhabitable. Certainly more wondrous than either event would be for anything then living to remember having once had distant ancestors who called themselves "human"...
It's compelling to me that the Earth and its moon are so tightly linked that their relationship is projected to outlast a life-providing sun. I believe this is moreso than any other moon-planet pairing in the solar system? Given what we know of incoming asteroids and comets, the probability of their impacts hitting with enough force at a trajectory you describe with enough significance to change the moon's orbit is expected to be low . And we're relatively confident of that?
I don't have numbers or references here, but my intuition from a lifetime of space nerding is that, if the moon were struck with enough retrograde force to materially lower its orbit, in the best case that impact would liberate debris of mass and vector such that our first concern would be planetwide disaster response. (In the worst case, it might shatter the moon entirely and distribute a significant fraction of its total mass across Earth's surface; in such a scenario, the survival of eukaryotic life anywhere on Earth qualifies as a million-to-one-shot win.)
But the odds of such a collision I suspect are significantly lower even than of a similarly sized impactor striking Earth. Granted that the moon helps a great deal in sweeping space near Earth of objects that might otherwise enter our atmosphere, but something with the kind of kinetic energy it would take to produce these outcomes isn't going to spend long enough within the gravitational influence of the Earth-Moon system to be significantly affected before impact. It'd be like trying to swerve an ICBM warhead by blowing really hard on it, and I choose that simile with care - if this ever does happen, I think it might constitute a clear indication that someone somewhere in the universe really hates us!
Do we have an idea of what percentage of impacts were prevented this way? What likelihood is there that the moon saved humanity (more than once?) since the time that we descended from the trees?
I imagine once you figure out which craters correspond to ones that came in at an angle which would have hit earth and compare that to all the impacts you have had on earth one could figure it out.
The thing is that on the moon the craters remain visible for a much longer period of time while on earth they get covered up by plate shifts, erosion, ocean impacts, etc. So instead it might be a way to calculate how many asteroids likely have hit earth in general throughout history whether we have found the craters on earth or not. Then you could calculate based on the size of the craters on the moon which ones would have been earth catastrophic events (taking into account any diminishing impact energy due to our atmosphere). Which would tell us how many the moon saved the earth from. In terms of how many since human ancestors were evolving we would have to then date earth catastrophic craters on the moon. I'm not sure if this can be done through photographs or if we would have to get surface samples.
Then comparing that number to the fraction of earth covered/protected by the moon to the total area on earth we would have a decent idea of how many of these events happened one earth even if we haven't discovered the evidence for them on earth.
The article doesn't seem to answer the question of why the heat plume distributed stuff on the nearside rather than evenly, or on the top side. If the south pole was hit, it seems like the heat should flow evenly on both sides, and if anything case the deposition to happen towards the north pole, rather than the near side.
Reading the linked paper and Wikipedia, it looks like the center of the KREEP concentration is roughly antipodal to the impact crater, which itself is not exactly on the south pole. So at least the symmetry side of things is in order. But yeah, this PR article is exceptionally bad at taking a long time to say almost nothing of interest.
Not much. The Earth subtends a width of only 2° in the Moon's sky - it covers only about 1/10000 of the possible approach vectors to the Moon.
Think about a lunar eclipse for comparison: the Earth intercepts the Sun-Moon vector for a couple hours every few months, roughly 1/10000 of the time.
The Moon is a smaller target (1/4 the diameter, 1/16 the cross section, also 1/81 the mass and gravity), so it gets hit less because of that, but not because of Earth shielding it.
I don't think that calculation is quite right. An asteroid on a collision course with the moon doesn't need to hit the Earth in order to avoid hitting the moon -- simply coming close to the Earth will alter its course.
It's just as likely that the Earth will perturb an object's course away from the moon as into it. Except if the object hits Earth itself, but the point is that's a pretty small percentage of cases, the Earth occupies only a small portion of the moon's sky.
Are the probabilities equal? I agree that they're both possible, but I don't have any clear intuition for why they should be the same -- or which would be larger if they're not the same.
> The nearside is home to a compositional anomaly known as the Procellarum KREEP terrane (PKT) — a concentration of potassium (K), rare earth elements (REE), phosphorus (P), along with heat-producing elements like thorium. KREEP seems to be concentrated in and around Oceanus Procellarum, the largest of the nearside volcanic plains, but is sparse elsewhere on the Moon.
Bait. Big pile of things we want, placed where we can see them but not easily reach...
A wild speculation: perhaps Moon is the huge asteroid that hit and liquefied the planet that was there before Earth, so some of its material sticked to that asteroid and formed Moon, while the rest formed Earth. In this case, the two sides of Moon show the direction of the impact.
I mean, the prevailing theory is that the Moon formed in the aftermath of the Theia–proto-Earth collision. Indeed the existence of the Moon is why the Theia hypothesis was proposed in the first place. But the bulk of Theia’s mass (which would have been ~10% of Earth’s mass) is thought to have mixed with Earth’s and sunk into the core/mantle, while most of the Moon is made of same material as the modern Earth’s crust.
However, the differentiation of the Moon’s near and far sides must have happened later, presumably during what’s called the late heavy bombardment (“late” is relative here; we’re still talking ~4 Ga ago). Although I believe some recent research has cast doubt on whether the LHB actually happened at all.
Oh, I remember that word now: "pseudoscience"; it used to be regurgitated everytime someone stepped into a pool of reality-altering facts. They never manage to pin down the 'pseudo' or the 'science', or contribute (like old-school hippies) anything to the collective.
The Moon is so much more interesting than most people think.