So does this imply that we'll never know if the Cambrian Explosion is actually an explosion or just a continuation from a previously unrecoverable geological record? Is it even possible to have complex multicellular life under snowball earth conditions?
>Although it’s likely down to a number of factors, one possibility is that Snowball Earth’s erosion was so significant that there wasn’t much topography left to erode when all was said and done. The planet simply needed to forge more land first, and that takes time.
The balance of earth is so interesting. The process that forges new land (volcanism) is the same process that beats back snowball earth and re-balances the atmosphere with more CO2.
> So does this imply that we'll never know if the Cambrian Explosion is actually an explosion or just a continuation from a previously unrecoverable geological record? Is it even possible to have complex multicellular life under snowball earth conditions?
That's a good question. I'm the first author of the new PNAS article discussed here (open access at https://doi.org/10.1073/pnas.1804350116). This does raise some questions about preservation bias and taphonomy, but there are areas we know escaped Neoproterozoic erosion (mostly at actively rifting continental margins) and we can find continuous sedimentary sections from the Cryogenian to the Cambrian -- and in these sections we still see a pretty rapid rise in complex shelly fossils in the early Cambrian. That said, when people first started talking about the "Cambrian Explosion", we didn't know much anything about the Ediacaran biota [1], the Ediacaran extension of the "Small Shelly Fauna" [2], or the Doushantuo Formation [3] -- so the evolutionary problem's not quite as bad as when Darwin first worried about it.
One new point to add is that erosion and comminution of this much crust may be expected to free up a lot of phosphorus stored in the igneous crust -- arguably the key limiting nutrient on geological timescales. This seems to be be consistent with previous observations of an increase in phosphorus abundance in sediments around Cryogenian times [4].
Oh, and regarding the survival of life through a Snowball Earth state, there's been some interesting discussion of potential refugia such as polynyas [1] and cryoconite ponds [2,3], though for context the most advanced multicellular organism I've seen anyone propose prior to the last snowball is still only a sort of sponge [4]
I find this stuff just absolutely fascinating, but have trouble finding reputable documentaries on the subject. YouTube is filled with "History" channel crap, and it's so disappointing to get all excited to learn, then be shown the crap they push out.
So, while apologizing for hijacking with an OT comment, do you have any docs you can recommend on the topic of geologic formation/periods of the Earth?
NOVA's always been my favorite science documentary series. I don't know if they've ever covered snowball earth, but they have a somewhat recent series on geological history of North America: https://www.pbs.org/wgbh/nova/series/making-north-america/
Likely there were a few 'explosive' events near the time of the Cambrian explosion. The Avalon Explosion [0,1] was about 33 million years earlier than the Cambrian Explosion. I would bet that our understanding of Life's history on Earth, and in the solar system in general, is only at the very beginning. Likely, our descendants will be looking at this understanding just like we look back at old 1890's paleontologists and their laughable Dinosaur models.
As an aside: I think that ML and RNNs would be a great tool for paleontologists to use for fossil hunting. Not just for automated drones scanning the lonelier places on Earth, but just to identify potentially 'rich' areas in the first place. Via petroleum studies, we know a fair bit about the Earth and the layers of sediment under it. Using that data, I think it may be possible to help narrow down the areas where good fossilization may have occurred and then send the armies of grad students out to those places, helping increase the percentages for finds.
> The process that forges new land (volcanism) is the same process that beats back snowball earth and re-balances the atmosphere with more CO2.
And I believe volcanism, at least the sort that is most common today (that from ocean-margin subduction zones, rather than that from spreading zones like Iceland or hotspots like Hawaii) results from subducted sediments melting into magma, with their melting points reduced by the presence of subducted water. If so, then do we have the large amounts of sediment, created by the snowball-earth glaciation, setting the stage for the volcanism that ends it?
There are fossils of Precambrian, post-snowball multi-cellular life, but they are not very much like, and nowhere near as diverse, as what appeared in the Cambrian, so I think the explosion still looks like a real event and not just an artifact of an imperfect record.
Since the erased part of the geological record starts 100’s of millions of years before the climate event that froze everything, do we even know that some earlier civilization didn’t force the climate off balance with e.g. greenhouse gasses, which ended up obliterating all multicellular organisms, and wiping the geological evidence?
Other recent news about ocean current disruptions, and methane melting feedback loops in the artic suggest we might be headed that way too...
And it would be written in the genes - models of evolution that work out timing from mutation rates and assays of genetic sophistication don't show any hidden episodes in the record.
Kudos to real scientists who bit by bit uncovers what happened in earths past, in ever-increasing resolution.
Whether "snowball earth" is accurate or not, what appears in outline is an earth that would have been uninhabitable for humans under most of, and even in relative recent, geological history.
It begs the question of how we might deal with the situation where the globe once again becomes uninhabitable (if we survive that long): terraforming or cocooning. The latter seems the best bet.
Or maybe even more tantalising, how did the previous sentient species deal with it. Or to reverse that question, is there something a hypothetical species, akin to our own, could have constructed that could have withstood Snowball Earth ? :)
It sounds easy enough, objects in space, large structures, unnatural concentrations of radioactive materials, sure, but over millions of years with kilometers of the top crust simply shaved off and recycled through the core of the planet?
It's amusing our notion of "glacial" loses meaning over such time-spans. How can it do anything, since glaciers just lie there. But over millions of years, it's a high-speed efficient grinding machine the size of a planet.
Conversely, as to how we might deal with the situation, ludicrous though it might seem with our advances and technology, maybe we simply can't. Even a passive beacon on the moon which wouldn't have suffered from Snowball Moon; it seems plausible enough, but it has to withstand at least 250 million years of the moon's night/day cycles. Is there something we could build right now that could withstand that?
Maybe? Probably? But for now I'm content the Snowball Earth hypothesis spices up a lot of Lovecraft stories. "And with strange aeons even death may die” indeed.
The society would have to have never discovered radioactivity to go undetected this long. In comparison it will take millions of years to wipe out human traces ever since the first atomic testing was done.
Even things on dead planet like the moon can't survive indefinitely because meteors either striking it or dusting it, even if we etched the moon with nuclear blasts contour would get fuzzy and disappear over million years.
One option would be to put in one Lagrange point some high quantity of radioactive material. You'd need to pick quantity and material well tho, because material with short hair life would cool off to get and become just a rock and materials with too long half life would be very hard to detect due their low emissions.
Give it a shape nature would have had time to replicate like an empty cylinder and it would likely be the best way to leave artifact for million years into the future. Won't be able to store any meaningful information beyond "someone was here" and future people coming to bertrand teapot style of argumentation against God would have a hell of a shock upon rediscovery
Almost all of the moon's surface is older than the ~500MYA scale we're talking about. It has the occasional impact, like Earth does, but the overwhelming majority of those craters you see are from the early bombardment. The dark splotches visible on the near side, the maria, are mostly flat volcanic plains laid down toward the end of that period about 3BYA, and are visibly lacking in craters.
That’s the large impacts. The Moon gets hit by ~2800 kg of meteor material per day, though this likely has been decreasing over time.
It’s about one ‘bullet’ going ~38,000 mph per 379 square kilometers. But times 365 days a year you’re at 1 bullet per square km/year. Over 500 million years that’s 500 bullets per square meter which would heavily damage if not outright destroy any structure and cover it in lunar dust.
PS: The 38,000 mph issue is hard to conceive of assuming similar weight it’s ~2,500 times the kinetic energy of a 9mm bullet. Military rail guns are aiming for Mach 7+ which is ~1/40 the kenetic energy of a similarly massed meteor.
Yeah, but those aren't going to destroy a structure, just put holes in it the way they put little holes in the surface. You can look at the moon landing videos and see surfaces that have been consistently flat and undisturbed at scales greater than cm for billions of years.
It kind of depends on what you mean by structure. Buildings would not survive. The great perimids would look like odd hills after this stuff.
Moon is x impacts per day * 365 days * 500 million / 37.9 million square kilometers = 4815 days worth of bombardment per km squared. Each day represents 2800 kg so each square meter gets hit with ~ 13.5 kg if stuff going 17,000 m/s.
1/2 Mass * velocity squared. 13.5 kg * 17,000^2 = 1950750000j or 1/2 a ton of TNT per square meter. Except the force is conctrated in one direction so it’s closer to 1 to 3 tons of TNT for every single square meter.
Now it’s diffent because these impacts don’t happen at the same time. But they also don’t happen from a single direction so taller structure would be hit along their surface.
(Edit: this was written to respond to your original comment about the Sears tower, not the one that you have up now which is about ancient egyptian physics or something. I'm too lazy to type up another response. I'll just leave it at "you're wrong" and depart)
> But if you put say the sears tower there 500 million years ago it would not be recognizable as a structure
That's just not true. Look at the Apollo 11 photos. Those exposed rocks are 3+ billion years old (six times older than the timescale we're talking about) and they're certainly not covered in a mound of dust. A 500m-scale structure on the moon would absolutely still be standing, absent really really bad luck.
Look at the size of those rocks. Fist sized chunks of rubble are not a structure. After the surface solidified it was continuously bombarded and broken into tiny fragments. That same thing would happen to buildings on those time scales.
Picture a cooling pile of molten rock that’s solidified, now you can’t pick that up. You can only pick up fragments that are blown apart and looking at those pictures their are plenty of fragments you need to dig to find the solid rock.
Additionally, useful surface structures probably would be made in part of lightweight materials transported from Earth; a useful base would likely be largely subsurface. There's no particular reason why an entrance to such a base need be durable or monumental, or even directly visible with human eyes (or artificial aids thereto) from many kilometres above (let alone from Earth).
Apart from radio beacons and similar navigational aids, there's good reason to think a predecessor terrestrial spacefaring civilization would see very differently from mammals closely related to humans.
(Along those lines, one can imagine a predecessor Earth civilization whose leading species is comfortable in a temperature or pressure that humans could not tolerate, and that their comfortable working conditions would drive the location and composition of a lunar base for them. Even our own species had (and has) mountain-dwelling civilizations in environments challenging to subtropical coastal people. If they had been in the Space Race, mountain-dwellers might have had some advantages in needing to haul around less atmosphere (being comfortable with a higher cabin altitude), and they're the same species as the first Americans and Soviets in space.)
It starts out as a hypothetical between a couple of researchers that resulted in a paper on the longest-lasting effects of human civilizations.
It's a good read, but the summary is that human civilization has resulted in atmospheric changes which will be detectable 100 million years from now, and we've got that much atmospheric evidence buried in geology without similar evidence for a past civilization.
> how did the previous sentient species deal with it
I like your thinking :-) It's the kind of fantasizing that I'm convinced is at the core of human progress, based on hardly more than a number of currently unknowable "what if"s.
It is, as you point out difficult to know if such a species could have existed. But if they did and if they tried to survive, we might be fairly certain that they failed barring something even more fantastical, currently only to be found in the darkest corners of youtube.
The real utility of this line of thought is IMO how we might try to survive the same conditions, since there is no real assurance that it could never happen again. We don't have the answer yet, agree.
At the time scale of billions of years, the question of whether there was sentient life on Earth is roughly equivalent to asking if there is sentient life on other planets, since Earth is very nearly (but not quite) another planet at that time scale. If sentient life arose that quickly that means it is even easier than we thought it was to arise, by quite a bit. The fact we don't see any in the sky would strongly suggest (but not prove) to me that there was not a previous civilization. (The most parsimonious explanation as to why there aren't a lot of civilizations in the sky is that for yet fuzzily-understood reasons, they can't arise much more quickly. [1])
Plus, while the narrative that "evolution increases the complexity over time" isn't as strong as some may suppose, it does provide a ceiling to complexity over time, and I'd say most of the evidence that we have would strongly suggest that there isn't any feasible way that the biology of a billion years ago could have supported intelligent life, because that ceiling is just too low. Today, there seems to be several possible feasible lines for intelligent life (birds, sea mammals, octopus) in the "short-term" multi-million-year future, with homonids getting there first, but a billion years ago I don't think that was the case. I suspect your average ant nowadays is more intelligent that much of what was around back then.
Oh, and, yes, we could build something that would survive on the moon. In particular, we're not obligated to put only one thing on the moon; that's an artifact in thinking with the exact precise technology of today, where's it's really expensive. In another 50-100 years it's quite plausible that putting up such a momument would be considered on the scale of an ambitious art project, and it's not hard to imagine dozens and hundreds of such monuments being put on the moon over time. Local materials can be used for bulk, and the only upper limit on the size of such a momument would be the energy available for whatever it is you wanted to do with it. Moving around local materials and building the equivalent of a pyramid would be almost feasible today ("almost" here being "less than a factor of magnitude of development away"), for instance, and melting & refreezing mass quantities of lunar surface for some visually-obvious effect is eminently practical if you have fusion. (And if you have fusion that can use the He3 on the moon, downright cheap.) It's not hard to conceive of monuments miles in size, or if you assume self-repairing or -replicating machinery, you can make something visible from Earth feasibly. Even with only solar power, that just slows the project down. Had that been done billions of years ago, some of them (or some of it) may have been destroyed by meteors but the vast majority would still be there. In another 100-200 years of reasonably-projected technological advance we'd be able to consider completely resculpting the effective appearance of the surface of the moon, for any number of reasons and in any number of ways. The moon shows no evidence of this, which would be enough to say that if there is a sentient civilization in Earth's past, it would put the Great Filter back in front of us again. (Albeit much more weakly, since only one civilization may have died before resculpting the moon.)
It's still faintly possible that we'll explore the moon in more depth that we have today and find "something" interesting. The fact that it's soooo untouched at a bulk scale suggests to me it's not likely, but it's possible some civilization got to where we are today, +/-50 years, and then died back, leaving just a trace on the moon, just as we have so far.
(IMHO, the most recent paper on the Fermi paradox from a couple of months ago puts the Great Filter behind us fairly firmly, by showing there's no compelling reason to assume the sky should be full of civilizations.)
[1]: It is well-understood that you need at least some time for complex elements to develop, and in enough quantity to form useful planets and such, so you do need at least some time for some stellar generations, but there is no currently-known reason that I'm aware of that the sky should not be inhabited by a multi-billion-year old civilization. On a cosmic scale, Earth isn't that late to the party in some sense, but looking at its history it still seems like you could shave some billions of years off of its history and still get an "Earth-like planet" somewhere else.
It is interesting how they “break up” dating depending on the time frame, for example some dating is only measured by “eon” (half a billion years), whereas the “finest” measurement seems to be “age” which corresponds to single digit millions of years.
A bit humbling to think that all of humanity can “fit” in the smallest geological measure of time.
Yeah, I think the vastness of geologic time has been aptly described as "geology’s signal contribution to human thought" -- the same way astronomy showed us we weren't the literal center of the universe. I think about Myr and Gyr timescales every day at work, but it's still hard to really intuitively grasp.
Obligatory John McPhee:
> Numbers do not seem to work well with regard to deep time. Any number above a couple of thousand years—fifty thousand, fifty million—will with nearly equal effect awe the imagination.
> Consider the earth’s history as the old measure of the English yard, the distance from the king’s nose to the tip of his outstretched hand. One stroke of a nail file on his middle finger erases human history.
Wow, I always assumed that complex life prior to our own was unlikely because it would have left a trace that we could detect. But if there is a plausible mechanism by which all such traces would have been erased, then who knows what might have happened deep in those billions of years when supposedly only single-celled life existed?
Perhaps Earth’s previous inhabitants triggered runaway global cooling, effectively hitting the reset switch back to single-celled life. Perhaps they escaped to Venus and vowed not to let the same thing happen there, but got it wrong in the other direction.
I'd be hesitant to attribute any sort of hypothetical causes, but it's fun to also consider such scenarios when thinking just one rock a bit further out. Mars was at one time a warm, watery planet not dissimilar to Earth. It's going to be extremely interesting once we get feet on the ground and can start really digging into the planet's past, quite literally. Most tantalizing of course is that it seems to have had all that was necessary to see the development of life. In many ways even finding absolutely no evidence of life at all will be as exciting as finding the opposite. Okay definitely not as exciting, but it'd certainly be really quite interesting!
Even on shorter timescales, there are 100+ ton milled monoliths all over the world, which are seemingly 4000+ years years old. Yet the civilizations of 4000 years ago don’t seem to have known how to mill such stones. It probably wasn’t until the 19th century at the earliest that we “re-learned” the basic skills required.
My default assumption is that history has only picked up, at best, the latter cycles on big time scales.
Maybe. But the political/industrial class would have mind-fucked us into clamoring to do nothing about it. If they went to Venus, only the people who could afford or command it would have made it, and they would have died off almost immediately because they had no minions to hold up the bottom layers of civilization.
It's interesting how most comments here immediately see this gap in our history book of Earth as a potential time span during which another advanced civilization could have developed and gone extinct (my mind did the same). Meanwhile the article without much discussion jumps to this: "complex life first emerged when Snowball Earth’s monstrous mealtime came to an end."
Snowball Earth theory says entire earth was covered in an ice sheet dozens of miles high. There might have been a ring around the equator of unfrozen water or slush.
It seems very hard for life to survive under those conditions, let alone complex life, let alone advanced life / civilizations.
What evidence do you have that there is some such thing as a "balanced world ecology" at all? It seems to me that all the evidence, in addition to logic, is in the opposite direction.
I guess I share your problem, I’m not sure “balanced” is the right word. You could have two species, a single celled animal and a single celled plant and ostensibly that would be “balance”.
Maybe a better word for what is at risk is “diversity”. At this time there are still wild ecologies with incredible diversity in all three phases of water on Earth, the frozen, the liquid, and the steamy.
And there are also partly dead places. The American Midwest is largely ecologically dead, although we know before the European settlers came there was stable soil and incredible biodiversity there.
But balance and biodiversity are connected. In a diverse ecology, you can remove any species, or turn any dial slightly, metabolism will dip, and then roar back into full power because there is so much latent genetic material in the ecology ready to go.
That’s been destroyed in a place like the Midwest. If you stop putting oil into that ecology, the metabolism would plummet, and it would take a million years to return to anything close to what it was before European settlers.
In a so-called “balanced” ecology, metabolism would rebound on a scale of decades or even seasons.
The moral assumption underlying this is that the most metabolism per square foot of solar energy is the most good.
Ok, I think we are talking about two different things:
One thing is biodiversity and the ecological resilience of biodiverse systems, of which there are many (still) where different species live in a healthy, productive and dynamic balance. These habitats are under attack for sure, spurred by industrial production modes of various kinds.
Quite another thing is the notion (represented by GP if I'm correct) that the whole earth somehow is a balanced system, were it not for greedy humans. This is a mystical belief that I don't see any proof of.
It is far-fetched not to think that comet impacts, massive volcano eruptions and/or solar radiation variance accidentally could make most if not all ecological systems devoid of life, quite without human intervention.
tl;dr, It was a light-hearted ironic idea, not some statement on the impending downfall of human civilization
"that the whole earth somehow is a balanced system, were it not for greedy humans"
This was in no way implied by what I said!
I think the word balance is justified here, the word I got wrong was ecology (I meant climate, but it was late, and I didn’t expect such a defensive response to my joke,…).
Either way, both the climate and ecology of earth work by balancing conflicting interests and drivers. food chains, carbon cycles, etc.. all are based on interlocking processes that combine to create a system that is stable at a macro level (Of course localized factors can make things seem much less stable). But on the whole, these systems are balanced. Things periodically come along and upset that balance, and it takes a while for the system to adjust and re-balance, typically with a result that is different from before.
My point was that it would be ironic if ANY civilisation got to the level where it could alter these systems meaningfully, but by doing so, and not understanding what/how they were doing things, created a situation where not only were they wiped-out, but also all trace of their technology was wiped-out too.
I accept that this exact scenario is extremely unlikely, as our current models predict that in these situations, at least some of the population would survive due to those localized factors, but the civilisation could easily be destroyed by sudden and climactic shifts.
It's unclear (to the best of my knowledge) if we would expect the historical record of such a thing to be carried by these people, but a lot of the detail of our knowledge of roman and pre-roman times(1,000s years, not millions) has been derived from archeological records, so it's not unreasonable to assume that if Ice were to scour all hard evidence of such things from the surface of the earth, then the knowledge of such may die out or become so garbled that it ceases to be believed.
Of course there /are/ parallels with the situation modern humans find ourselves in. I think there's little doubt that what we do has an effect on the balance of the world's climate and ecological systems (you eat a chicken, that has affected the food chain by an infinitesimal amount), but how much impact we will have, and our ability to comfortable adapt to any resulting changes would require a much longer response, and isn’t relevant to my original post at all :)
What I meant was that this hypothetical civilisation supposedly flourished in a particular environment. If their actions altered that environment radically enough to wipe them out, AND wipe out all traces of their existence, then that would be an interesting idea to consider
> the survivors would have lived relatively comfortably in smaller populations in habitats
A million years gives a pretty long time for unlikely events to occur that could finish the job of wiping them out. Wars and engineering accidents and diseases and such.
Like you I tend to be of the opinion our human civilization will survive any kind of global cataclysm that Earth could throw at it... But I am less convinced a population forced under a million individuals could survive - million years just under the normal chaos of existing.
I suspect there is a minimum population and geographic diversity required for our long term survival. Not sure where those red lines are though.
> it is hard to imagine a culture having sufficient technological capability to cause climate change without also achieving space flight
What does that get you? You can’t orbit Earth for a million years without refueling. And the rest of the bodies is pretty inhospitable. What’s the best case there, a million people on Mars with a few decades of preparation? What’s the probability of such an outpost surviving?
Look at our own history as a species. We seem to have expanded outward from equatorial regions that were lush, warm, and filled with wildlife. Nearly every need we had could be met with minimal effort. And we rapidly moved outward into areas that were cold, desolate, dark, and where even not freezing to death would have been a challenge.
In more modern history people set off into seas with no idea where or if they would ever end, in ships no way well designed for oceanic travel. And there was a very real belief that these seas were infested with giant monsters that would destroy ships. Many would have seen such voyages as little more than suicidal endeavors at one time.
Getting even more modern consider space. We went from the New York Times publishing pieces suggesting that space flight would be impossible (arguing that rockets would lack anything to 'push' against in space) to having a permanently manned station orbiting the Earth some 16 times a day, along with all of its crew.
The point of this is that everything seems impossible at a distance, yet rarely is that the case. We feel like we're near the top of a mountain looking at the final insurmountable face. Only to eventually discover that not only is that face entirely surmountable, but it was nowhere near the top. Once we've colonized Mars, and perhaps other inner system bodies, people will again eventually consider such achievements of little relevance with interplanetary travel becoming as mundane as intercontinental flight is today. And they too will ponder off thinking about how unimaginable colonizing planets in star systems outside our own would be... and the cycle continues. The only reason colonizing Mars, indefinitely, seems out there is because that's where we currently are on the mountain.
Climate change is certainly surmountable. What makes me sad is what’s lost along the way. Humanity survived the colonization of the America’s. But it also lost some irrecoverable things.
I can definitely understand this point of view, but there's also another way of looking at things.
Nobody in a million years would have ever wished for something like the Black Death. It was a catastrophe like none before (at least that we know of) and certainly none since. It claimed the lives of upwards of half of the human population in Europe. Such a catastrophe, yet it played a major role in setting into the motion the social changes that would eventually lead to the end of feudalism and the advent of mercantilism. It played a key role in shaping a vastly more liberated society.
Or consider nuclear weapons. These weapons were only used against other people twice. It was a heinous act with immense cost. Yet far beyond just ending that war - as was the purpose of their use, those weapons of unimaginable destruction signaled the end of all outright warfare between developed nations. It makes one wonder if in some parallel world, if the weapons' destructive power was never demonstrated on humans might we have been more likely to eventually end up in nuclear annihilation with countries, such as in the Cold War, far more willing to press that red button?
Should human caused catastrophic climate change should come to pass it's not particularly hard to foresee the lessons and behaviors we might learn and enact from such. And one can only imagine what social changes might occur. Of course would indeed be much nicer if this was not how we collectively learned, but a civilization and a young child have one thing very much in common. You can tell them not to put their finger in the fire all you want, yet they will inevitably learn that lesson not by instruction but by scorched digit.
TL;DR; Earth appears to have been covered by miles deep ice for many hundred millions of years during the last billion, and that caused normal geological leftovers of the period to be nonexistent. The best info for that period is stuff frozen into zircon crystals, which scientists think supports the ice hypothesis.
>Although it’s likely down to a number of factors, one possibility is that Snowball Earth’s erosion was so significant that there wasn’t much topography left to erode when all was said and done. The planet simply needed to forge more land first, and that takes time.
The balance of earth is so interesting. The process that forges new land (volcanism) is the same process that beats back snowball earth and re-balances the atmosphere with more CO2.
It's a bit old and cheesy, some of the info might be outdated, but this is a great episode on this topic: https://www.youtube.com/watch?v=XEiu611KsUo