Seems inconsistent to bring up nanotech, etc., yet keep climate hell as a fixed background. Of course attempted fixes will run into issues, small or catastrophic, but they're bound to exist.
I think climate change is inevitable. Whether from human causes or from the natural climate cycles we must assume that the sea levels will change, even if only temporarily from a historical perspective. Even if the sea levels only rise 1 metre for 5 years, that is still a big refugee problem.
What is worrying is that those most likely to be affected by rising sea levels are in general those least able to cope with it. We must assume that there will be hundreds of millions of refugees, from Bangladesh, from the tiny Pacific Islands, or even from New Orleans and Venice. Will humanity let them die? If not then those of us living in higher elevations must start planning now for how we will accommodate them.
I agree that climate hell appears to have already started. But 500 years is a while, and I'd expect attempts to roll it back starting by 400 years before that time. (Assuming with the author that tech civ continues, etc.) The most plausible reasons against would be conflict or a dominant power that prefers the warmer globe.
Five hundred years out is an awfully far distance into the future. I could see most of this happening in 200 years, or probably less.
One of the problems with making predictions like this is that technology begins to compound and affect itself in weird ways - a book I have discusses how once you have proper mind-machine interfaces and can copy a person at will, one of the most efficient ways to travel becomes transmitting yourself at light-speed and getting a new body once your persona has been downloaded at your destination, rather than traveling in a physical body. This is something I had never considered before encountering it in that book, as much as it is a logical step from cybernetic brains and being able to back yourself up.
Similarly, racism, sexism and language issues being to disappear as you approach a higher level of computer integration. Racism and sexism become quaint ideas when most people can change to a body of the opposite sex whenever they want, and skin color becomes a matter of aesthetic choice. You might end up with wholly different types of racism (or perhaps species-ism) due to deliberate genetic changes to adapt to different environments resulting in wildly different types of humans, or due to experiments to bring certain species to human levels of intelligence (apes, dolphins, octopi?)
I find it interesting that he would have geopolitical boundaries exist at all. The idea of nations may well be an outdated one a couple hundred years hence. As we continue to improve our abilities to manufacture and grow things on ever smaller and more controlled scales, there may come a point where we no longer need massive structures of human organization like nations, corporations, etc. On the flip side, these things could become more ingrained and efficient such that we approach hive-like efficiency/societal structure (group minds etc.)
I suppose I find most of these speculations rather tame. I think that things will change a lot faster, and in a lot bigger ways, than described here.
And in 500 years I would imagine "human" being almost beyond comprehension to us now. Like, consciousness woven into spacetime at the subatomic level, crazy.
I think one of the only things we can be reasonably certain about is energy. Many or even most of the changes Charlie listed would require changing much of the technology deployed on our planet (except of course those changes that are more or less inevitable, like rising sea levels). Changing any of the hardware in our world on a large scale requires massive amounts of energy, and energy follows rules that don't change at all over a 500 year timescale.
Fusion seems to be inevitable. I can't say I agree with people who say it'll never be competitive with other energy sources. All that has to be done is to solve the engineering hurdles required to make fusion scalable, and perhaps to add the capability to use fusion reactions that make use of a greater variety of elements. (And yes, those are huge challenges, but we're talking 500 years of advanced engineering operating on something that already works in a simple prototype system.) Once that has been achieved, fusion power can outperform >any< other terrestrial energy source (except perhaps fission), as a matter of physics. I imagine the economics of that will fall into place once that massive supply of energy is made potentially accessible, since there will undoubtedly be demand for titanic amounts of cheap and reliable energy.
"GM mangroves that can grow in salinated intertidal zones and synthesize gasoline, shipping it out via their root networks, is one option."
That one sentence overloaded my system with a visual day-dream about the potential for our future - the way it's written evokes that famous Bladerunner line:
"I've seen things you people wouldn't believe. Attack ships on fire off the shoulder of Orion. I watched C-beams glitter in the dark near the Tannhauser gate. . ."
A few dozen words in both quotes that evoke such richness. Beautiful work.
As a later comment points out, in a manner as arresting as the vision it criticises, roots are how plants get their inputs. The soil feeds the plants! - not the other way around.
The actual relationship is more two-way, as plant roots exist in symbiosis with mycorrhizae, providing sugar in exchange for minerals and other micronutrients.
This is factually inaccurate. Plants are not built out of soil, they are built out of air and water, the contribution from the soil is comparatively minor. Especially if symbiotic mycorrhiza are in play in which case only a tiny handful of minerals and phosphorous is pulled from the ground. The great bulk of the mass of a tree is cellulose and lignin, and that comes straight out of photosynthesis and from atmospheric CO2 and ground water.
Speaking from the UK I take issue with his: "the English speaking world was a few million barbarians occupying a handful of damp islands on the outer fringes of Europe". We may then have been limited in extent and geography as this suggests,but we were supporting the three oldest universities in the world, excepting Bologna,and had a general education system that was about to produce Shakespeare and which had already produced Chaucer many others of his quality.
These brusque assumptions about the past tend to reduce my faith in this analysis of the future.
It is of course hard to predict 500 years out. Hell, it's hard to predict 20 years out. Did anyone really see the world of today even 20 years ago?
But I'll take my own fanciful stab.
I don't foresee either an energy or a climate crisis. There is a hard limit on how expensive energy gets because at some point you can turn totally renewable energy into a fuel of some sort, ideally taking CO2 out of the atmosphere to do it. It's not cost effective now because energy is so cheap. But like I said: there's a limit to how expensive it can get.
The bigger problem (IMHO) is going to be certain elements and metals that aren't so easily replaced. I agree with the author that getting certain elements from space is going to be economically tricky (rather than technologically tricky) compared to how cheap it is to pull stuff out of the ground.
You can recycle iron to a degree but a certain amount is lost through corrosion/rust. Rare earth elements are harder to replace.
I do foresee there being a lot less of us and that is probably going to be a traumatic change.
Sadly I don't foresee a huge presence in space. The energy costs, particularly when you look at even the most optimistic models of interstellar travel in particular, are just too extreme even with perfect mass-to-energy conversion.
Change like evolution is often perceived to be smooth but it's not. Our world like life itself is shaped by key, often small, events. Europe in 1914 was a powderkeg in 1914 but one man's death triggered a sequence of events that resulted in World War One, the armistice for which sowed the seeds for World War Two. One could argue that if the Archduke had lived something else would've triggered the war and you may well be right. Still how different might the world be if, say, JFK was killed by a chance bullet in World War Two?
As far as longevity goes, that's a tough one. I expect there'll be a certain class of people who live much better and longer than others but then again the history of the world thus far is those kinds of technological advancements always trickle down eventually. Living forever? I have my doubts.
Artificial intelligence as always is the sleeping giant of the future. I believe that to be inevitable and the effects could be profound to put it mildly.
I too believe the nation states of today mostly won't exist in 500 years.
The bigger problem (IMHO) is going to be certain elements and metals that aren't so easily replaced. I agree with the author that getting certain elements from space is going to be economically tricky (rather than technologically tricky) compared to how cheap it is to pull stuff out of the ground.
I'm not convinced that 'economically tricky' will mean anything in 500 years. Assuming that we have essentially unlimited free energy, and AI capable of autonomously handling things like building, manufacturing and farming (which doesn't necessarily require strong AI), the cost of everything will ultimately head towards zero, surely?
We'll always be able to find something which is still expensive. And everything has scaling limits. For example our "essentially unlimited" energy source might give us enough to power a 21st-century lifestyle essentially free, but might still be prohibitively expensive when you try to use it for intergalactic travel, or for running computer simulations of googols of universes.
"Free energy" is a misnomer. There is the cost of fuel and the cost of what produces the energy (capital, maintenance, land, labour, etc costs).
The attraction of fusion is "free energy" in that hydrogen is plentiful (even deuterium is plentiful, tritium less so). Helium is not unlimited at least here on Earth and we're busy pissing away our supply on party balloons thanks to a US government decision to sell its strategic reserve in the 90s.
But a fusion plant is expensive. It costs money for the raw materials and the labour to build and maintain it such that the energy it produces--if it ever becomes economically viable, which is far from certain--will not be "free".
Computing power might be cheap but it's not free. An AI/robot won't be "free" in the same sense either. They'll cost money to build. Those resources will cost money.
Also, not all energy is the same. Plants that power the electrical grid are one thing. The energy required to hurtle a large metal object into space is something else. Fusion might work quite well for infrastructure but will it be made to work where we currently use kerosene and oxygen? That vehicle too costs money.
Sure, I get all that. But we're talking about 500 years hence. I just don't believe that the costs you're listing should be relevant in that time frame. If you have AI that is 500 years more advanced, you're effectively removing human involvement in things like mining raw materials, maintaining and building plants. No singularity required.
The cost of mining raw materials goes to zero if we can build a machine that can build other machines that can autonomously space mine.
The cost of producing energy goes to zero if we can build machines that can build and maintain energy plants.
I would be surprised if much of this hadn't occurred within 200 years, let alone 500.
I agree with you, and that's how I see it working too. And the capitalist system won't work in that setup; it would naturally lead to a single person at the apex owning all the capital (self-reproducing capital => whoever has the best growth function dominates in inverse exponential time), and all the rest of us either being servants or information workers (since everything physical can trivially be done by machines).
Add in strong AI, and you remove the need for information workers; we'd all be servants in the employ of a single CEO at the apex; or servants to other servants; or prostitutes, or some other power relation not reproducible from machines because of wanting the authenticity of a person. I don't see such a state as stable (certainly not in a democracy), and if it existed tomorrow, there would be a revolution. But of course the transition will be gradual, so there won't be a revolution; but something post-capitalist, post-scarcity, will need to emerge to stop blood flowing.
The cost of the raw material used to make fuel is absolutely trivial in all nuclear power plants. The market price of uranium would have to increase by more than three orders of magnitude to increase the cost of produced electricity by 10%. At that point, we have unlimited supplies in seawater.
The capital costs of power plants have trended up as safety and monitoring requirements have risen. Given sufficient automation, AI, and simpler and fundamentally more safe designs (which do not need as much active safety), these costs can probably be brought down.
I agree with most of your comments, with the exception of your concerns about continued material scarcity and human longevity.
Regarding material scarcity, I think space mining becomes a lot more economically viable once you have not only extraordinarily cheap energy, but also super light, super strong materials. Ralph Merkle talks about a diamondoid space shuttle (composed of perfectly arranged carbon atoms) weighing a few hundred pounds and getting to orbit with only a hundred dollars worth of fuel: http://www.youtube.com/watch?v=cdKyf8fsH6w
Also, people have been talking about space elevators forever, once we crack economically viable carbon nanotube production, reducing the cost to orbit by something like 99%.
Most importantly, when people talk about molecular manufacturing and molecular assemblers, they never seem to see the other side of the coin - molecular disassemblers - essentially "just in time" goods. When you can assemble and disassemble atoms at will, you essentially have programmable matter, and therefore you can do much more with less material.
As I mentioned below, you could also make the case that highly realistic VR systems would drastically reduce our demand for materials. After all, who needs to buy an actual Porsche when they can just close their eyes and have an experience much better than the real thing.
Regarding longevity, it seems to me that this is a cognitive bias because of the audacity of the idea, similar to the widespread skepticism towards human flight a hundred years ago. The idea is just so outlandish, and goes against thousands of years of philosophical and theological thought on accepting the inevitability of death, that people (myself included) instinctively recoil from it.
Assuming a 500 year time span - or even a 100 year one - and assuming that humans have developed the capability to manipulate matter at will, can scan and monitor the human body at extraordinarily high fidelity, model and simulate the body in great detail, and can experiment and iterate on those experiments at light speed with the aid of AI and neural interfaces - the death of death seems inevitable.
The problem with space mining when you look a the periodic table there is just not a lot of useful and rare elements. And all space mining is just extracting those elements so you need to have a gap that's worth the effort to go and collect even after LEO. When it comes to space mining think: Diamonds are carbon which is cheap. Even gold mostly just sits around, there is little point in increasing supply when so little of it is used. So yea, you might go and collect a few asteroids for some platinum etc but crossing the 1/10,000th of word GDP takes more than just a few useful elements.
PS: Outside of Fission or Fusion nothing ever actually runs out. Worst case, start mining dumps and river beds etc.
We are talking about a five hundred year time line. As I mentioned in my post, there will be massive reductions in the cost to orbit and back. Hell, we are already witnessing the very beginnings of this phenomenon with SpaceX.
Certainly in five hundred years time, and possibly just in a few decades, it will make about as much economic sense to import rare materials from orbit as it now does to import them from China.
Also, I'm making this argument primarily to counter concerns of material scarcity brought up by cletus. As I stated above, with this time span, I think we will likely have developed molecular assemblers and disassemblers, leading to essentially programmable matter and perfect recycling, which would lessen our need for materials.
You could also make the case that super realistic VR systems would drastically reduce our demand for materials. After all, who needs to buy an actual Porsche when they can just close their eyes and have an experience much better than the real thing.
For limits see some quick math, you can probably mine down about 20 miles without getting to fancy in 2512 esp relative to a space elevator. Texas is 20 miles * 268,800 sq miles = 10^16 cubic meters. Platinum has an average rarity ~5 millionth of a gram per kg. aka 5 parts per billion which works out to ~10,000,000 cubic meters in the top 20 miles of Texas granted your playing with density's etc but 10,000,000 tons is reasonable estimate compared to around ~100 tons mined each year. Now we might be better off mining asteroids than Texas, don't assuming we need to leave the planet any time soon.
PS: It may be a mainstay of sci-fi, but there is little actual evidence that asteroids are going to have particularly high levels of any of the really rare stuff. (other than H3)
It seems like we are having two different arguments. My main point here has been that material scarcity will likely be a non-factor in the future. You seem to be in agreement with that point, but seem dead set against the practicality of space mining.
Throughout my comments I've maintained that molecular assemblers/disassemblers (and possibly VR) should drastically lessen the amount of materials we consume. I'm simply saying that if we do run into scarcity issues, worst case, space mining should be many, many orders of magnitude cheaper within this time span.
Right now the US goes to the expense of floating rare earth elements on freighters from halfway across the globe, simply because we don't want to deal with the pollution, real property rights, safety issues, regulatory issues, and eyesores resulting from US mining operations. With the expected reductions in cost to achieve orbit, in 2112 the asteroid belt could very easily be the new China.
Now you could argue that the same breakthroughs that allow cheaper space mining would allow us to cleanly and efficiently extract resources in greater number from the earth - "molecular mining", if you will. That may be the case, but it's really impossible to predict to that degree of specificity at this point in time. We're probably arguing over what in the future would be the equivalent of going to the Walmart down the block or the Target across town to get a package of batteries. It probably doesn't matter.
Besides, the amount of materials we need really depends on how ambitious humanity wants to get:
>PS: It may be a mainstay of sci-fi, but there is little actual evidence that asteroids are going to have particularly high levels of any of the really rare stuff. (other than H3)
Untrue. Iridium is the rarest element in the Earth's crust. The majority of the known deposites come from asteroids.
It's not just Iridium, either. Compare these two charts:
I was puzzled by this, since obviously there are elements that are more rare than iridium, so I checked the original data source. They eliminate most radioactive elements which kind of makes sense. I was a bit surprised to learn that polonium and radium are less common in the crust than iridium. They also eliminate noble gases from the list, of which krypton, xenon, and radon turn out to be rarer in the crust than iridium. Also a couple sources have rhenium rarer than iridium.
(I'm not trying to be pedantic and start an argument, but just fill in some information in case anyone else wondered about this data.)
> The bigger problem (IMHO) is going to be certain elements and metals that aren't so easily replaced. I agree with the author that getting certain elements from space is going to be economically tricky (rather than technologically tricky) compared to how cheap it is to pull stuff out of the ground.
I don't think this is a real issue. Expensive metals are recycled extremely efficiently even today. This is only going to get easier as we go on.
> You can recycle iron to a degree but a certain amount is lost through corrosion/rust. Rare earth elements are harder to replace.
Iron is the metal that least needs recycling. There are deposits for essentially unlimited amounts at prices not absurdly higher than the present market conditions. Also, should energy get cheaper, iron would be greatly substituted with aluminium in construction. (And the aluminium supplies of the surface of the earth are essentially infinite.)
The talk about REE is largely misguided. REE are not rare. There are exploitable deposits pretty much in every country that's larger than Luxembourg and has exposed rock. The world deposits are greatly larger than any reasonable use we have for them.
The reason REE is in the news is that extracting it is an extremely dirty process, and if you want to do it in a first-world country, you have to pay very much to clean up after you. China captured nearly all of the world production not because they have a large share of a limited resource, but because they allowed miners to dump their separation waste in rivers. This makes REE extraction cost a fraction what it would be if you had to rebury all those unwanted heavy metals, and so the Chinese mines so depressed the market price that all the non-subsidized mines elsewhere in the world shut down. As the Chinese started restricting exports (which is only shrewd of them, considering the massive societal cost they bear of the cheap production), the market price rose again and mines elsewhere started to open. The Mountain pass mine is now finally entering large-scale production, and will very soon make the US a net exporter of REE.
Do you really feel that going all over the planet and turning the crust to sand is a viable long-term solution? Many mining engineer types and even geologists see no problem with this approach, but consider Appalachian coal: just because they can "put that mountain back together just as before", the result is far from the original. It's like the policy of "moving" wetlands to ease development in my area; almost looks ok, but the result is a local bio-disaster.
> I don't foresee either an energy or a climate crisis. There is a hard limit on how expensive energy gets because at some point you can turn totally renewable energy into a fuel of some sort, ideally taking CO2 out of the atmosphere to do it. It's not cost effective now because energy is so cheap. But like I said: there's a limit to how expensive it can get.
I used to agree with you until I read this terribly thought-provoking article[1]. Now I'm not as sure. It was published by the Oil Drum, a blog I subscribe to for oil industry news, so the article doesn't have a hidden agenda.
The key insight I gleaned from it was the concept of the energy cost of energy sources.
I used to think that even if wind power wasn't as efficient as oil now, eventually oil prices would rise and wind would become a viable alternative.
However, what the article showed was that wind power itself uses oil in the manufacturing of the materials, shipping and construction of the wind mills, etc. You can think of the concept of the energy return on energy invested. And as the supply of oil dwindles and costs rise, that EROEI will change.
Oil at its start had an EROEI of 100:1, which means you could get a hundred barrels of oil for the cost of using one. Now it's at 20. Wind energy has an EROEI of about 20 over the lifetime of the equipment, but unfortunately costs a lot of energy up front, and only recoups that energy over time.
So the two issues the article raises is that as the cost of oil increases, it affects the EROEI of the renewable resources, and that because the majority of renewable resources all have upfront energy costs, they'll get hit extra hard. Politically, it will always make sense in the short term to cancel the renewable energy projects since you're using a great deal of the increasingly rare energy for payoffs in the future, when that energy could go to cost of living and make things better now.
I really think you'd enjoy the article if you read it, so I encourage you to do so. ("You", being cletus, wouldn't have posted this otherwise. You seem very smart and I've enjoyed your posts.)
The "energy trap" as described in the linked article would indeed be terribly troubling in a centrally planned economy. I'm still optimistic (for the moment) that there are private players who would cheerfully make those large investments today for a chance at owning a future slice of the energy pie.
" getting certain elements from space is going to be economically tricky (rather than technologically tricky) compared to how cheap it is to pull stuff out of the ground"
That completely changes when you want to use those elements in space, rather than on earth. I think that could be the more normal thing to do; if we go to space, it will be to stay there. Why lift stuff out of earth's gravitation well that you can get from the arteries belt?
Highly doubt any of the countries that exist today will exist 500 years from now. Honestly I highly doubt most of them will exist 50 years from now. Most developed countries are headed for their day of reckoning as the bills for their welfare states come due. Combined with the fact that every developed country has a negative birthrate due to these policies delaying adulthood many countries will collapse from just demographic changes in the next 50 years.
How do people still believe in run away global warming? There's been absolutely ZERO warming for the lat 16 years, the Earth warmed for 15 years before that, then cooled for 40 years before that. Cloud formation, the major environment influencer of global climate, now seems to stem from cosmic rays.
I do believe space travel, specifically mining, will become much more prevalent. This will eliminate any resource problems. As for energy advances in solar technology and nuclear (fusion or fission) should drastically lower the cost of energy by an order of magnitude from today's prices.
"The half-life of a public corporation today is about 30 years: ten half-lives out — 300 years hence — we may expect only one in a million to survive."
Am I the only one who read this and went "Wait, 10 half-lives... that's 1/(2^10)... that would mean about 1 in 1,000 survive -- not 1 in 1,000,000."?
Ah -- didn't see that. Wasn't so much a criticism (it doesn't take away from the article at all) as it was an observation that something really trivial stuck in my head ;)
With all the talk of engineered intelligence and huge biotech advancements, I think there will be a massive space expansion, and I'm surprised to see it doubted.
First off, a human settlement on Mars, while technologically challenging, would need a relatively small initial population to get started sustainably (say, 2000 people). All of the advancements in food and energy production mentioned in the article could be used to provide for a colony there.
The OP talks about genetically engineered animals for food production, but they could also be engineered to better work and thrive in space-based industries; collecting raw materials, zero-gravity manufacturing, energy collecting, etc. Sophisticated, autonomous machines could do all that as well, so that actual humans have very little need to spend much time out in space, other than traveling between planets and settlements. Or perhaps all travel is virtual, using telepresence to see the solar system.
Machines built in space don't have the costs to get up there in the first place, other than the initial factories and material harvesting equipment.
Great thought-exercise, though. I love thinking about this stuff, and I think our generation has to start anticipating these changes. Some other commenters pointed out this all may happen far sooner than 500 years, so we just might need to be ready.
I'm glad he didn't take the doom and gloom approach. We do keep seeing the bad side (overpopulation, disease, environmental degradation, wars etc) but slowly and surely the opposite has been happening. Prosperity has been improving things for (virtually) everyone, not just a few westerners. And people do strange things once prosperous - they protect the environment, have more greenery (compare richer versus poorer neighbourhoods), buy organic, electric cars, contribute to charity etc. The question is can we continue to improve prosperity, and there is no reason to believe it won't keep happening. Matt Ridley of "The Rational Optimist" has a lot of material to substantiate that.
Here is a quick TED talk and a transcript of the opening to get you going.
"When I was a student here in Oxford in the 1970s, the future of the world was bleak. The population explosion was unstoppable. Global famine was inevitable. A cancer epidemic caused by chemicals in the environment was going to shorten our lives. The acid rain was falling on the forests. The desert was advancing by a mile or two a year. The oil was running out, and a nuclear winter would finish us off. None of those things happened, (Laughter) and astonishingly, if you look at what actually happened in my lifetime, the average per-capita income of the average person on the planet, in real terms, adjusted for inflation, has tripled. Lifespan is up by 30 percent in my lifetime. Child mortality is down by two-thirds. Per-capita food production is up by a third. And all this at a time when the population has doubled."
I don't really see the point of speculating about 500 years out. Wouldn't it be a lot more useful to figure out how to increase the rate of innovation and discovery now?
For example, if innovation happened in flight and most people could fly at hypersonic speed within 10 years, the world becomes even smaller. Cure most cancers within 10 years instead of 50 and maybe the "next Steve Jobs" will get another 2-3 decades.
There are lots of big problems that would could solve decades sooner if we could find better ways to innovate now.
I enjoyed this article and I agree with most of the prediction on this timescale. I'm surprised, though, that he didn't mention one issue in particular: the continued development of human-computer interaction and its impact on the world's socioeconomic makeup.
Over the past 20-30 years, computers have completely changed the way people interact with the world. Most highly-educated people's lives center around their iPhones, laptops, iPads, etc. As time goes on, automation will likely continue to advance. As computers surpass humans in efficiency for more and more jobs, what role will the uneducated play? Clearly, wealth will continue to concentrate in the hands of fewer and fewer highly educated individuals. Will the rich exploit the poor, or will the need for consumers cause the wealthy to redistribute wealth just so that people have money to buy their goods? Will ordinary people end up like the passengers of the spaceship in WALL-E? Let's go a step further: if the so-called singularity occurs, what is the need for people in general?
The point of the technological singularity insofar as it interacts with reasonable prediction of the future is that reasonable predictions tell you that it is next to impossible to make any sort of reasonable cultural/climate/landmass/population/other soft prediction much past this century.
Hard takeoff scenarios seem to be unlikely (no self-improving AI going from human project to godlike status in a couple of hours while rolling its own molecular nanotechnology foundation). The reasons for this are the same reasons that make rapid global takeover of the internet by a viral monoculture unlikely today: results take effort, some results are opposed, some results are intrinsically hard, no breakthrough happens in a vacuum.
But: by 2040 it will be possible to emulate human brains the hard way. By all means tell me that every human culture will refrain from taking full advantage of all that can follow from that over the decades that follow. The economic benefits of human and built-from human intelligences instantiated to order are incredible. The possibilities spiraling out from that are so much greater than everything that has come before that it becomes very, very hard to say what comes next.
You could see a world in which there are trillions of entities of human and greater intelligence by 2100. With their own cultures, so much greater and broader and more varied than ours as to make us the first snowflake in the blizzard. They may or may not have access to molecular nanotechnology and as much of the solar system as they care to begin making over by then. What will they build? How can you say? Culture determines creation.
Equally, you might not see that world. But it looks most plausible to me that software life will erupt from our culture in much the same way as we erupted from Greek tribes thousands of years ago - but much more rapidly. If you can show me you can sensibly predict the details of today's world by an examination of the Mediterranean Bronze Age, then I might be more inclined to think it possible to talk about what lies on the other side of emulated human intelligence.
Insofar as fiction goes, the technological singularity has been done. It's sliding out of fashion for the moment. The authors have done their job, pointed it out, on to the next thing. But the real world continues to trundle along as it always has: the underlying trends and emerging technological capabilities remain even as fashions in SF come and go.
Charles Stross is not unaware of this; he's written multiple novels on the topic of the singularity including "Accelerando" and "Rapture of the Nerds". I recommend either of them if you're interested in the subject
This blog post is simply a different approach to the topic. Basically, what would happen if the singularity never happens and it's just us humans trying to solve the problems on our planet.
The author continues to compare now to 500 years ago, while I think a lot of his prognostications might right on target I think that these advances will come much quicker than 500 years. If we took the magnitude of advances for humanity from 1512-2012, and we applied those magnitudes today that it would happen in the next 100 years (5:1). I do like his non doom-and-gloom approach (disclaimer aside). I agree with some of the other comments that if you ask any human at anytime if the world is in its worst state in history, the answer will be yes and I think the author understands this isn't always the case. Great read.
Definitely a fun read, lots of things to nod and shake your head at. For example if we've mastered the fusion power generation process then rather than carbon remediation we may find we have to burn things occasionally to boost atmospheric CO2, the reasoning goes that we've basically converted all of the arable surface area to 'farm' land, we have converted all of our industrial and motive mechanisms (cars/trucks/trains) to electricity, we use the Fischer-Tropch process to create jet fuel which can take CO2 out of the air, so not only are anthropogenic sources of CO2 but natural sources (forest fires) are removed from the system. If we are pulling energy geothermally out of volcanic hot spots that will leave their tops just frozen enough to not erupt (another giant source of atmospheric CO2).
It is really really hard to predict past a point where the energy problem becomes 'solved.'
I also expect that all of our computing / electronics devices will be essentially 3D printed out of carbon in various forms (tubes, balls, graphene) providing the various roles of switch, conductor, gate, and substrate. Those will be connected by a mesh of networking that is a couple of gigabits wireless and perhaps a terabit when hard connected. The low marginal cost of bandwidth will make it pretty much non-blocking bandwidth everywhere.
I expect we'll be eating a manufactured food product that is tasty and nutritious and the domestication of livestock and the use of any other living organism (including plants) will be considered 'quaint'. No one will have to go hungry because the combination of low cost energy and the ability to assemble food will allow for free 'food' (although not designer, "high end" food).
I think the more interesting question though comes from biology, which is to say if we have completely decoded cellular biology then there won't be any excuse for being sick or not 'healthy' (and by that I mean optimal function of all organs including the brain). At some point during the development of that capability the aspects of ones genetics which determines sexual orientation will be completely mapped out and understood and there will be a big debate about what we do about that, do we 'cure' homosexuality, do we offer to make everyone 'omnisexual' etc. There will be huge and heated debates about what is and what isn't normal.
I think it's a bit off on the predictions relating to energy. The best way to explain why is to borrow from Vinod Khosla's theory of energy black swans, and assume that the forms of energy we know and make use of today are going to be replaced by forms of energy we either don't know of or haven't yet managed to master.
500 years is simply a long, long, long time from now in terms of human progress. I think the energy description provided here might possibly fit a model of our energy mix 100 years from now. However, it's very unlikely to be the one we follow 500 years from now, simply because the basis for energy-related discoveries dictates that every few decades an entirely new form of energy is discovered and gets subsequently iterated upon until economically viable. It simply isn't factually reasonable to assume that we have already discovered all possible forms of energy production.
By the way, i did energy-related research which is why i wanted to point this out. Regardless of these flaws, I thoroughly enjoyed reading that essay.
tl;dr: energy-predictions 500 years out are not reasonable because of Vinod Khosla's theory of energy black swans.
I highly recommend reading through Charlie's Comments. They're just as good as the article and touch on everything from building construction to Scottish Independence to creating an atmosphere in the Vales Marineris rift valley on Mars.
Assuming that there is no great WWIII or equivalent cataclysmic event the world of 2512 is beyond our faintest imaginings and would likely be frightening to us.
I don't speak about nanotechnology or even brain-uploading and synthetic sentience, I speak about rather more mundane trends that are almost certain to continue.
For example, manufacturing. Today manufacturing is still rather similar in nature to the way it was in the 17th century, we just have a whole crap-ton more of it and it's easier to ship manufactured goods around the globe. But I believe we are reaching an inflection point on manufacturing. We will soon reach a point where manufacturing becomes entirely automated for huge classes of devices. All you'll need to do is upload a set of files to a server somewhere and press a button and then a factory will produce whatever it is you've designed, on very short notice and in arbitrary volumes. This alone is a transformative technology, but let's take it a step further, toward fully automated creation of machine tools and to factories themselves. The idea of an assembly line as this huge, fixed entity is due to the nature of our manufacturing technology, but it's possible that manufacturing facilities will themselves become disposable (likely recyclable) and transient. Manufacturing won't be something that people consume, it will be something that people do. More so, the ability of a small amount of capital machinery to boot-strap into the manufacturing capabilities of a developed nation will rapidly eliminate almost all remaining undeveloped parts of the globe. Imagine what happens when you can ship a few containers of equipment to, say, antarctica and start building out factories, tractors, automobiles, houses, etc, etc. with only an input of crude raw materials.
How this will transform the world is beyond me, but it will certainly change our perception of wealth and scarcity and the people living in a world with this technology will be as unfamiliar to people of today as people of today would be to stone age tribes. And this technology is not a 500 year technology, it'll likely arrive in the next hundred years at most.
Let's talk about drugs and surgery and self. Modern medicine is at best a century old, and in some ways perhaps even less. There will come a time, certainly within the next 500 years, when medical technology in the realm of mood alteration, behavior alteration, and cosmetic surgery are at a level which we would describe from the perspective of today as nearly perfectly effective. Imagine what happens when people can change their personalities and their mental capabilities at whim? If you find you're depressed you can fix that, effectively and permanently. If you have a mental illness such as, say, schizophrenia or pedophilia then you can fix that too. And if you are dissatisfied with your mood or your personality you can change that too. Do you want to be an alpha personality? Do you want to be a thrill-seeker? Do you want to be bubbly and happy all the time? Easy peasy. Do you dislike the way your face or body looks or works? You can change that too. You can have a stunningly attractive and physically fit body with ease, and you can look like a movie star.
To say that this will change society is a gross understatement. In many ways I think this will be a bigger challenge to the world than any other technological or environmental challenge. To be honest I think it will be a larger challenge for our species than even trying to co-exist with thermonuclear weapons.
As for space, I think it will affect our future a great deal but perhaps not as much as these other things. One thing a lot of people get wrong about space is imagining that it's hard. It's not, we've just been doing it very, very badly. For the same exact amount of money the world has spent on space so far we could have easily built orbital cities and moon bases housing hundreds. Not with revolutionary technology, not with some alternate and hugely more cost effective programs, but merely with applying proven and existing...
I hate replying to myself but I think this point is worth following up on re:space. Consider that by current estimates the global economy will be at a level of around a quadrillion dollars per year within the next 100 to 150 years. Now, let's say that developed countries put a priority of space science exploration and manned spaceflight at around 1 part per thousand of GDP, which is fairly close to what the G8 nations spend today. Assuming that the future world retains such a priority it would mean spending of a trillion dollars a year just a century or so out. Now think about that over centuries, hundreds of trillions of dollars of investment into space. I think that means that at a minimum you'll have self-sufficient off-Earth colonies with populations of millions. And that's without assuming breakthrough technologies.
Is solar shade so much hardrer to launch than retooling all the biology to live at 45C and still dealing with the world that sucks? Launching a large slightly opaque mirror to shade select aread of Earth does not seem impossible to me.
It seems he bet everything on climate being out of control.
> Is solar shade so much hardrer to launch than retooling all the biology to live at 45C...It seems he bet everything on climate being out of control.
This was the very first (of several) objections that I had.
Stross is a pretty good writer (at least, he can be at times), but every time he turns his hand to futurism I think he fails miserably. He's got a worldview that I think he's invested in, and he's got a tone (deflating what he sees to be the overenthusiastic techno-nerds) that he likes, and both make him pretty bad at prediction. He sees Moore's law in his own life, but fails to apply it or similar principles to the world going forward. If he was practicing futurism in 1912 he'd be writing that cars are inherently a stunt because we can never build enough roads or find enough fuel for them, and in the year 2412 people will be living in mile high brick building surrounded by a wasteland of horse manure from the perpetually animal-clogged streets.
There are so many problems with the "ZOMG we're all going to be roasted by global warming". I'll leave aside the fact that there's been no increase in average temperatures in 15 years (to avoid the whole "climate change denier" fight that no one wants to have) and just accept as given for this discussion that, yes, average temperatures might rise 2 or 3 C. Given that space launch gets cheaper every year, given that robots get better every year, given that manufacturing gets cheaper every year, etc., it will be trivial in 50 years - let along 500 - to have robots build huge solar shields in orbit, or have robots build huge dikes around our coastal cities (we reclaimed thousand of acres of land from the oceans in the middle ages - we can't do that in the 21st century?), or have giant naval cannons fire explosive shells full of light block aerosols into the upper atmosphere, or, or, or ...
There are so many ideas that aren't 50 years out - let alone centuries out - that can solve these problems.
I think that it's a truism that different countries have different default outlooks. It can't be taken too far, but there are archetypes. Russians are darkly amused by the inevitability of defeat. Americans are gee-whiz let's change the world neophytes. Germans are prone to being a bit dour, etc.
Stross seems to be in the mainstream of British / Scottish cultural thought (at least as it's been revealed to be by fiction, both science fiction and mainstream). Stereotypical American apocalyptic fiction, I suggest, is about raging against the problem and striving to overcome it...and British apocalyptic fiction is more often than not about coming to terms with it.
tl;dr I find Stross' futurism uninteresting and wrong-headed because he seems to find reasons to justify his slightly depressive theres-nothing-we-can-do attitude.
If your nation consists of 1/6th of the world's population, you bear 1/6th the burden of the global warming triggered by your fossil fuel use, but get 100% of the energy output from your fossil fuel use. Conversely, if you unilaterally decide to build a giant shade for the earth, you foot 100% of the bill yet only receive 1/6th of the overall benefits.
You can usually arrange in at least one ally (and now you're 2/6) and then tax other powers for premium features of the solar shade if they want them (that is, climate control).
"I'm also going to ignore space colonization, because I want to focus on this planet."
Europe changed when explorers "discovered" the new world. Saying you are only going to focus on "this planet" is like saying I am only going to focus on the "old world" when talking about earth 500 years ago.
In my mind the rest of the article is pointless because the author is using the old world way of thinking about this planet.
The fact is the exploration of space is very similar as what happened 520 years ago. What happens when the price of getting to orbit drops significantly because of reusable rockets? Already there are companies that are planning on mining astroids. Saying that this is not going to effect earth in a major way is not really looking at where earth will be in 2512.
Space exploration is going to define the next 500 years of humanity and of this planet just as exploration of the new world defined the last 500 years.
The author of the original article, Charles Stross, wrote a lengthy piece on space colonization a while back, explaining why he believes it's implausible, which may be why he's not examining it in more detail here:
Hard to miss the alarmist undertone here. He seems much more confident about the effects of climate change (or is that global warming?) than the effects of politics and technology. Compare:
"Sea levels will have risen by at least one, and possibly more than ten metres worldwide."
"Fission: will be in widespread safe use or completely taboo."
I think it's quite likely that within a couple of hundred years there will have been multiple changes that are completely beyond our current compression, that we couldn't even begin to speculate on. Nevertheless, I'll add my speculation to this rather interesting discussion:
The ease and volume of communication is bound to increase. Perhaps we communicate through technological telepathy, with anyone we want to. We share thoughts and senses with groups of people and solve problems by adding more brain power. The Mythical Man Month is no longer mythical. Learning and "news" become instant. Communication is probably faster than the speed of light.
Physical objects are only slightly constrained to their form and location. They can be transformed and moved almost as easily as energy can. Having something only requires thought and currency.
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[ 2.7 ms ] story [ 185 ms ] threadWhat is worrying is that those most likely to be affected by rising sea levels are in general those least able to cope with it. We must assume that there will be hundreds of millions of refugees, from Bangladesh, from the tiny Pacific Islands, or even from New Orleans and Venice. Will humanity let them die? If not then those of us living in higher elevations must start planning now for how we will accommodate them.
The Arctic League!
One of the problems with making predictions like this is that technology begins to compound and affect itself in weird ways - a book I have discusses how once you have proper mind-machine interfaces and can copy a person at will, one of the most efficient ways to travel becomes transmitting yourself at light-speed and getting a new body once your persona has been downloaded at your destination, rather than traveling in a physical body. This is something I had never considered before encountering it in that book, as much as it is a logical step from cybernetic brains and being able to back yourself up.
Similarly, racism, sexism and language issues being to disappear as you approach a higher level of computer integration. Racism and sexism become quaint ideas when most people can change to a body of the opposite sex whenever they want, and skin color becomes a matter of aesthetic choice. You might end up with wholly different types of racism (or perhaps species-ism) due to deliberate genetic changes to adapt to different environments resulting in wildly different types of humans, or due to experiments to bring certain species to human levels of intelligence (apes, dolphins, octopi?)
I find it interesting that he would have geopolitical boundaries exist at all. The idea of nations may well be an outdated one a couple hundred years hence. As we continue to improve our abilities to manufacture and grow things on ever smaller and more controlled scales, there may come a point where we no longer need massive structures of human organization like nations, corporations, etc. On the flip side, these things could become more ingrained and efficient such that we approach hive-like efficiency/societal structure (group minds etc.)
I suppose I find most of these speculations rather tame. I think that things will change a lot faster, and in a lot bigger ways, than described here.
And in 500 years I would imagine "human" being almost beyond comprehension to us now. Like, consciousness woven into spacetime at the subatomic level, crazy.
Fusion seems to be inevitable. I can't say I agree with people who say it'll never be competitive with other energy sources. All that has to be done is to solve the engineering hurdles required to make fusion scalable, and perhaps to add the capability to use fusion reactions that make use of a greater variety of elements. (And yes, those are huge challenges, but we're talking 500 years of advanced engineering operating on something that already works in a simple prototype system.) Once that has been achieved, fusion power can outperform >any< other terrestrial energy source (except perhaps fission), as a matter of physics. I imagine the economics of that will fall into place once that massive supply of energy is made potentially accessible, since there will undoubtedly be demand for titanic amounts of cheap and reliable energy.
"GM mangroves that can grow in salinated intertidal zones and synthesize gasoline, shipping it out via their root networks, is one option."
That one sentence overloaded my system with a visual day-dream about the potential for our future - the way it's written evokes that famous Bladerunner line:
"I've seen things you people wouldn't believe. Attack ships on fire off the shoulder of Orion. I watched C-beams glitter in the dark near the Tannhauser gate. . ."
A few dozen words in both quotes that evoke such richness. Beautiful work.
But, maybe in 500 years they'll have fixed this.
Wetland plants (like Mangroves) already transport substances from their leaves to their roots.
These brusque assumptions about the past tend to reduce my faith in this analysis of the future.
But I'll take my own fanciful stab.
I don't foresee either an energy or a climate crisis. There is a hard limit on how expensive energy gets because at some point you can turn totally renewable energy into a fuel of some sort, ideally taking CO2 out of the atmosphere to do it. It's not cost effective now because energy is so cheap. But like I said: there's a limit to how expensive it can get.
The bigger problem (IMHO) is going to be certain elements and metals that aren't so easily replaced. I agree with the author that getting certain elements from space is going to be economically tricky (rather than technologically tricky) compared to how cheap it is to pull stuff out of the ground.
You can recycle iron to a degree but a certain amount is lost through corrosion/rust. Rare earth elements are harder to replace.
I do foresee there being a lot less of us and that is probably going to be a traumatic change.
Sadly I don't foresee a huge presence in space. The energy costs, particularly when you look at even the most optimistic models of interstellar travel in particular, are just too extreme even with perfect mass-to-energy conversion.
Change like evolution is often perceived to be smooth but it's not. Our world like life itself is shaped by key, often small, events. Europe in 1914 was a powderkeg in 1914 but one man's death triggered a sequence of events that resulted in World War One, the armistice for which sowed the seeds for World War Two. One could argue that if the Archduke had lived something else would've triggered the war and you may well be right. Still how different might the world be if, say, JFK was killed by a chance bullet in World War Two?
As far as longevity goes, that's a tough one. I expect there'll be a certain class of people who live much better and longer than others but then again the history of the world thus far is those kinds of technological advancements always trickle down eventually. Living forever? I have my doubts.
Artificial intelligence as always is the sleeping giant of the future. I believe that to be inevitable and the effects could be profound to put it mildly.
I too believe the nation states of today mostly won't exist in 500 years.
I'm not convinced that 'economically tricky' will mean anything in 500 years. Assuming that we have essentially unlimited free energy, and AI capable of autonomously handling things like building, manufacturing and farming (which doesn't necessarily require strong AI), the cost of everything will ultimately head towards zero, surely?
The attraction of fusion is "free energy" in that hydrogen is plentiful (even deuterium is plentiful, tritium less so). Helium is not unlimited at least here on Earth and we're busy pissing away our supply on party balloons thanks to a US government decision to sell its strategic reserve in the 90s.
But a fusion plant is expensive. It costs money for the raw materials and the labour to build and maintain it such that the energy it produces--if it ever becomes economically viable, which is far from certain--will not be "free".
Computing power might be cheap but it's not free. An AI/robot won't be "free" in the same sense either. They'll cost money to build. Those resources will cost money.
Also, not all energy is the same. Plants that power the electrical grid are one thing. The energy required to hurtle a large metal object into space is something else. Fusion might work quite well for infrastructure but will it be made to work where we currently use kerosene and oxygen? That vehicle too costs money.
The cost of mining raw materials goes to zero if we can build a machine that can build other machines that can autonomously space mine.
The cost of producing energy goes to zero if we can build machines that can build and maintain energy plants.
I would be surprised if much of this hadn't occurred within 200 years, let alone 500.
Add in strong AI, and you remove the need for information workers; we'd all be servants in the employ of a single CEO at the apex; or servants to other servants; or prostitutes, or some other power relation not reproducible from machines because of wanting the authenticity of a person. I don't see such a state as stable (certainly not in a democracy), and if it existed tomorrow, there would be a revolution. But of course the transition will be gradual, so there won't be a revolution; but something post-capitalist, post-scarcity, will need to emerge to stop blood flowing.
The cost of the raw material used to make fuel is absolutely trivial in all nuclear power plants. The market price of uranium would have to increase by more than three orders of magnitude to increase the cost of produced electricity by 10%. At that point, we have unlimited supplies in seawater.
The capital costs of power plants have trended up as safety and monitoring requirements have risen. Given sufficient automation, AI, and simpler and fundamentally more safe designs (which do not need as much active safety), these costs can probably be brought down.
Regarding material scarcity, I think space mining becomes a lot more economically viable once you have not only extraordinarily cheap energy, but also super light, super strong materials. Ralph Merkle talks about a diamondoid space shuttle (composed of perfectly arranged carbon atoms) weighing a few hundred pounds and getting to orbit with only a hundred dollars worth of fuel: http://www.youtube.com/watch?v=cdKyf8fsH6w
Also, people have been talking about space elevators forever, once we crack economically viable carbon nanotube production, reducing the cost to orbit by something like 99%.
Most importantly, when people talk about molecular manufacturing and molecular assemblers, they never seem to see the other side of the coin - molecular disassemblers - essentially "just in time" goods. When you can assemble and disassemble atoms at will, you essentially have programmable matter, and therefore you can do much more with less material.
As I mentioned below, you could also make the case that highly realistic VR systems would drastically reduce our demand for materials. After all, who needs to buy an actual Porsche when they can just close their eyes and have an experience much better than the real thing.
Regarding longevity, it seems to me that this is a cognitive bias because of the audacity of the idea, similar to the widespread skepticism towards human flight a hundred years ago. The idea is just so outlandish, and goes against thousands of years of philosophical and theological thought on accepting the inevitability of death, that people (myself included) instinctively recoil from it.
Assuming a 500 year time span - or even a 100 year one - and assuming that humans have developed the capability to manipulate matter at will, can scan and monitor the human body at extraordinarily high fidelity, model and simulate the body in great detail, and can experiment and iterate on those experiments at light speed with the aid of AI and neural interfaces - the death of death seems inevitable.
PS: Outside of Fission or Fusion nothing ever actually runs out. Worst case, start mining dumps and river beds etc.
Certainly in five hundred years time, and possibly just in a few decades, it will make about as much economic sense to import rare materials from orbit as it now does to import them from China.
Also, I'm making this argument primarily to counter concerns of material scarcity brought up by cletus. As I stated above, with this time span, I think we will likely have developed molecular assemblers and disassemblers, leading to essentially programmable matter and perfect recycling, which would lessen our need for materials.
You could also make the case that super realistic VR systems would drastically reduce our demand for materials. After all, who needs to buy an actual Porsche when they can just close their eyes and have an experience much better than the real thing.
For limits see some quick math, you can probably mine down about 20 miles without getting to fancy in 2512 esp relative to a space elevator. Texas is 20 miles * 268,800 sq miles = 10^16 cubic meters. Platinum has an average rarity ~5 millionth of a gram per kg. aka 5 parts per billion which works out to ~10,000,000 cubic meters in the top 20 miles of Texas granted your playing with density's etc but 10,000,000 tons is reasonable estimate compared to around ~100 tons mined each year. Now we might be better off mining asteroids than Texas, don't assuming we need to leave the planet any time soon.
PS: It may be a mainstay of sci-fi, but there is little actual evidence that asteroids are going to have particularly high levels of any of the really rare stuff. (other than H3)
Throughout my comments I've maintained that molecular assemblers/disassemblers (and possibly VR) should drastically lessen the amount of materials we consume. I'm simply saying that if we do run into scarcity issues, worst case, space mining should be many, many orders of magnitude cheaper within this time span.
Right now the US goes to the expense of floating rare earth elements on freighters from halfway across the globe, simply because we don't want to deal with the pollution, real property rights, safety issues, regulatory issues, and eyesores resulting from US mining operations. With the expected reductions in cost to achieve orbit, in 2112 the asteroid belt could very easily be the new China.
Now you could argue that the same breakthroughs that allow cheaper space mining would allow us to cleanly and efficiently extract resources in greater number from the earth - "molecular mining", if you will. That may be the case, but it's really impossible to predict to that degree of specificity at this point in time. We're probably arguing over what in the future would be the equivalent of going to the Walmart down the block or the Target across town to get a package of batteries. It probably doesn't matter.
Besides, the amount of materials we need really depends on how ambitious humanity wants to get:
http://en.wikipedia.org/wiki/Matrioshka_brain
Untrue. Iridium is the rarest element in the Earth's crust. The majority of the known deposites come from asteroids.
It's not just Iridium, either. Compare these two charts:
https://en.wikipedia.org/wiki/File:Elemental_abundances.svg and https://en.wikipedia.org/wiki/File:SolarSystemAbundances.png
Why are they so different? Basically all the heavy and iron-loving stuff sank.
https://en.wikipedia.org/wiki/Iron_catastrophe https://en.wikipedia.org/wiki/Planetary_differentiation
(I'm not trying to be pedantic and start an argument, but just fill in some information in case anyone else wondered about this data.)
See http://en.wikipedia.org/wiki/Abundances_of_the_elements_(dat... and http://en.wikipedia.org/wiki/Abundance_of_elements_in_Earths...
I don't think this is a real issue. Expensive metals are recycled extremely efficiently even today. This is only going to get easier as we go on.
> You can recycle iron to a degree but a certain amount is lost through corrosion/rust. Rare earth elements are harder to replace.
Iron is the metal that least needs recycling. There are deposits for essentially unlimited amounts at prices not absurdly higher than the present market conditions. Also, should energy get cheaper, iron would be greatly substituted with aluminium in construction. (And the aluminium supplies of the surface of the earth are essentially infinite.)
The talk about REE is largely misguided. REE are not rare. There are exploitable deposits pretty much in every country that's larger than Luxembourg and has exposed rock. The world deposits are greatly larger than any reasonable use we have for them.
The reason REE is in the news is that extracting it is an extremely dirty process, and if you want to do it in a first-world country, you have to pay very much to clean up after you. China captured nearly all of the world production not because they have a large share of a limited resource, but because they allowed miners to dump their separation waste in rivers. This makes REE extraction cost a fraction what it would be if you had to rebury all those unwanted heavy metals, and so the Chinese mines so depressed the market price that all the non-subsidized mines elsewhere in the world shut down. As the Chinese started restricting exports (which is only shrewd of them, considering the massive societal cost they bear of the cheap production), the market price rose again and mines elsewhere started to open. The Mountain pass mine is now finally entering large-scale production, and will very soon make the US a net exporter of REE.
I used to agree with you until I read this terribly thought-provoking article[1]. Now I'm not as sure. It was published by the Oil Drum, a blog I subscribe to for oil industry news, so the article doesn't have a hidden agenda.
The key insight I gleaned from it was the concept of the energy cost of energy sources.
I used to think that even if wind power wasn't as efficient as oil now, eventually oil prices would rise and wind would become a viable alternative.
However, what the article showed was that wind power itself uses oil in the manufacturing of the materials, shipping and construction of the wind mills, etc. You can think of the concept of the energy return on energy invested. And as the supply of oil dwindles and costs rise, that EROEI will change.
Oil at its start had an EROEI of 100:1, which means you could get a hundred barrels of oil for the cost of using one. Now it's at 20. Wind energy has an EROEI of about 20 over the lifetime of the equipment, but unfortunately costs a lot of energy up front, and only recoups that energy over time.
So the two issues the article raises is that as the cost of oil increases, it affects the EROEI of the renewable resources, and that because the majority of renewable resources all have upfront energy costs, they'll get hit extra hard. Politically, it will always make sense in the short term to cancel the renewable energy projects since you're using a great deal of the increasingly rare energy for payoffs in the future, when that energy could go to cost of living and make things better now.
I really think you'd enjoy the article if you read it, so I encourage you to do so. ("You", being cletus, wouldn't have posted this otherwise. You seem very smart and I've enjoyed your posts.)
[1] http://www.theoildrum.com/node/8526
That completely changes when you want to use those elements in space, rather than on earth. I think that could be the more normal thing to do; if we go to space, it will be to stay there. Why lift stuff out of earth's gravitation well that you can get from the arteries belt?
How do people still believe in run away global warming? There's been absolutely ZERO warming for the lat 16 years, the Earth warmed for 15 years before that, then cooled for 40 years before that. Cloud formation, the major environment influencer of global climate, now seems to stem from cosmic rays.
I do believe space travel, specifically mining, will become much more prevalent. This will eliminate any resource problems. As for energy advances in solar technology and nuclear (fusion or fission) should drastically lower the cost of energy by an order of magnitude from today's prices.
Hahahahaha
Good trolling, you'll get lots of bites.
Am I the only one who read this and went "Wait, 10 half-lives... that's 1/(2^10)... that would mean about 1 in 1,000 survive -- not 1 in 1,000,000."?
First off, a human settlement on Mars, while technologically challenging, would need a relatively small initial population to get started sustainably (say, 2000 people). All of the advancements in food and energy production mentioned in the article could be used to provide for a colony there.
The OP talks about genetically engineered animals for food production, but they could also be engineered to better work and thrive in space-based industries; collecting raw materials, zero-gravity manufacturing, energy collecting, etc. Sophisticated, autonomous machines could do all that as well, so that actual humans have very little need to spend much time out in space, other than traveling between planets and settlements. Or perhaps all travel is virtual, using telepresence to see the solar system.
Machines built in space don't have the costs to get up there in the first place, other than the initial factories and material harvesting equipment.
Great thought-exercise, though. I love thinking about this stuff, and I think our generation has to start anticipating these changes. Some other commenters pointed out this all may happen far sooner than 500 years, so we just might need to be ready.
Here is a quick TED talk and a transcript of the opening to get you going.
http://www.ted.com/talks/matt_ridley_when_ideas_have_sex.htm...
"When I was a student here in Oxford in the 1970s, the future of the world was bleak. The population explosion was unstoppable. Global famine was inevitable. A cancer epidemic caused by chemicals in the environment was going to shorten our lives. The acid rain was falling on the forests. The desert was advancing by a mile or two a year. The oil was running out, and a nuclear winter would finish us off. None of those things happened, (Laughter) and astonishingly, if you look at what actually happened in my lifetime, the average per-capita income of the average person on the planet, in real terms, adjusted for inflation, has tripled. Lifespan is up by 30 percent in my lifetime. Child mortality is down by two-thirds. Per-capita food production is up by a third. And all this at a time when the population has doubled."
For example, if innovation happened in flight and most people could fly at hypersonic speed within 10 years, the world becomes even smaller. Cure most cancers within 10 years instead of 50 and maybe the "next Steve Jobs" will get another 2-3 decades.
There are lots of big problems that would could solve decades sooner if we could find better ways to innovate now.
Over the past 20-30 years, computers have completely changed the way people interact with the world. Most highly-educated people's lives center around their iPhones, laptops, iPads, etc. As time goes on, automation will likely continue to advance. As computers surpass humans in efficiency for more and more jobs, what role will the uneducated play? Clearly, wealth will continue to concentrate in the hands of fewer and fewer highly educated individuals. Will the rich exploit the poor, or will the need for consumers cause the wealthy to redistribute wealth just so that people have money to buy their goods? Will ordinary people end up like the passengers of the spaceship in WALL-E? Let's go a step further: if the so-called singularity occurs, what is the need for people in general?
Hard takeoff scenarios seem to be unlikely (no self-improving AI going from human project to godlike status in a couple of hours while rolling its own molecular nanotechnology foundation). The reasons for this are the same reasons that make rapid global takeover of the internet by a viral monoculture unlikely today: results take effort, some results are opposed, some results are intrinsically hard, no breakthrough happens in a vacuum.
But: by 2040 it will be possible to emulate human brains the hard way. By all means tell me that every human culture will refrain from taking full advantage of all that can follow from that over the decades that follow. The economic benefits of human and built-from human intelligences instantiated to order are incredible. The possibilities spiraling out from that are so much greater than everything that has come before that it becomes very, very hard to say what comes next.
You could see a world in which there are trillions of entities of human and greater intelligence by 2100. With their own cultures, so much greater and broader and more varied than ours as to make us the first snowflake in the blizzard. They may or may not have access to molecular nanotechnology and as much of the solar system as they care to begin making over by then. What will they build? How can you say? Culture determines creation.
Equally, you might not see that world. But it looks most plausible to me that software life will erupt from our culture in much the same way as we erupted from Greek tribes thousands of years ago - but much more rapidly. If you can show me you can sensibly predict the details of today's world by an examination of the Mediterranean Bronze Age, then I might be more inclined to think it possible to talk about what lies on the other side of emulated human intelligence.
This blog post is simply a different approach to the topic. Basically, what would happen if the singularity never happens and it's just us humans trying to solve the problems on our planet.
It is really really hard to predict past a point where the energy problem becomes 'solved.'
I also expect that all of our computing / electronics devices will be essentially 3D printed out of carbon in various forms (tubes, balls, graphene) providing the various roles of switch, conductor, gate, and substrate. Those will be connected by a mesh of networking that is a couple of gigabits wireless and perhaps a terabit when hard connected. The low marginal cost of bandwidth will make it pretty much non-blocking bandwidth everywhere.
I expect we'll be eating a manufactured food product that is tasty and nutritious and the domestication of livestock and the use of any other living organism (including plants) will be considered 'quaint'. No one will have to go hungry because the combination of low cost energy and the ability to assemble food will allow for free 'food' (although not designer, "high end" food).
I think the more interesting question though comes from biology, which is to say if we have completely decoded cellular biology then there won't be any excuse for being sick or not 'healthy' (and by that I mean optimal function of all organs including the brain). At some point during the development of that capability the aspects of ones genetics which determines sexual orientation will be completely mapped out and understood and there will be a big debate about what we do about that, do we 'cure' homosexuality, do we offer to make everyone 'omnisexual' etc. There will be huge and heated debates about what is and what isn't normal.
500 years is simply a long, long, long time from now in terms of human progress. I think the energy description provided here might possibly fit a model of our energy mix 100 years from now. However, it's very unlikely to be the one we follow 500 years from now, simply because the basis for energy-related discoveries dictates that every few decades an entirely new form of energy is discovered and gets subsequently iterated upon until economically viable. It simply isn't factually reasonable to assume that we have already discovered all possible forms of energy production.
By the way, i did energy-related research which is why i wanted to point this out. Regardless of these flaws, I thoroughly enjoyed reading that essay.
tl;dr: energy-predictions 500 years out are not reasonable because of Vinod Khosla's theory of energy black swans.
I don't speak about nanotechnology or even brain-uploading and synthetic sentience, I speak about rather more mundane trends that are almost certain to continue.
For example, manufacturing. Today manufacturing is still rather similar in nature to the way it was in the 17th century, we just have a whole crap-ton more of it and it's easier to ship manufactured goods around the globe. But I believe we are reaching an inflection point on manufacturing. We will soon reach a point where manufacturing becomes entirely automated for huge classes of devices. All you'll need to do is upload a set of files to a server somewhere and press a button and then a factory will produce whatever it is you've designed, on very short notice and in arbitrary volumes. This alone is a transformative technology, but let's take it a step further, toward fully automated creation of machine tools and to factories themselves. The idea of an assembly line as this huge, fixed entity is due to the nature of our manufacturing technology, but it's possible that manufacturing facilities will themselves become disposable (likely recyclable) and transient. Manufacturing won't be something that people consume, it will be something that people do. More so, the ability of a small amount of capital machinery to boot-strap into the manufacturing capabilities of a developed nation will rapidly eliminate almost all remaining undeveloped parts of the globe. Imagine what happens when you can ship a few containers of equipment to, say, antarctica and start building out factories, tractors, automobiles, houses, etc, etc. with only an input of crude raw materials.
How this will transform the world is beyond me, but it will certainly change our perception of wealth and scarcity and the people living in a world with this technology will be as unfamiliar to people of today as people of today would be to stone age tribes. And this technology is not a 500 year technology, it'll likely arrive in the next hundred years at most.
Let's talk about drugs and surgery and self. Modern medicine is at best a century old, and in some ways perhaps even less. There will come a time, certainly within the next 500 years, when medical technology in the realm of mood alteration, behavior alteration, and cosmetic surgery are at a level which we would describe from the perspective of today as nearly perfectly effective. Imagine what happens when people can change their personalities and their mental capabilities at whim? If you find you're depressed you can fix that, effectively and permanently. If you have a mental illness such as, say, schizophrenia or pedophilia then you can fix that too. And if you are dissatisfied with your mood or your personality you can change that too. Do you want to be an alpha personality? Do you want to be a thrill-seeker? Do you want to be bubbly and happy all the time? Easy peasy. Do you dislike the way your face or body looks or works? You can change that too. You can have a stunningly attractive and physically fit body with ease, and you can look like a movie star.
To say that this will change society is a gross understatement. In many ways I think this will be a bigger challenge to the world than any other technological or environmental challenge. To be honest I think it will be a larger challenge for our species than even trying to co-exist with thermonuclear weapons.
As for space, I think it will affect our future a great deal but perhaps not as much as these other things. One thing a lot of people get wrong about space is imagining that it's hard. It's not, we've just been doing it very, very badly. For the same exact amount of money the world has spent on space so far we could have easily built orbital cities and moon bases housing hundreds. Not with revolutionary technology, not with some alternate and hugely more cost effective programs, but merely with applying proven and existing...
It seems he bet everything on climate being out of control.
This was the very first (of several) objections that I had.
Stross is a pretty good writer (at least, he can be at times), but every time he turns his hand to futurism I think he fails miserably. He's got a worldview that I think he's invested in, and he's got a tone (deflating what he sees to be the overenthusiastic techno-nerds) that he likes, and both make him pretty bad at prediction. He sees Moore's law in his own life, but fails to apply it or similar principles to the world going forward. If he was practicing futurism in 1912 he'd be writing that cars are inherently a stunt because we can never build enough roads or find enough fuel for them, and in the year 2412 people will be living in mile high brick building surrounded by a wasteland of horse manure from the perpetually animal-clogged streets.
There are so many problems with the "ZOMG we're all going to be roasted by global warming". I'll leave aside the fact that there's been no increase in average temperatures in 15 years (to avoid the whole "climate change denier" fight that no one wants to have) and just accept as given for this discussion that, yes, average temperatures might rise 2 or 3 C. Given that space launch gets cheaper every year, given that robots get better every year, given that manufacturing gets cheaper every year, etc., it will be trivial in 50 years - let along 500 - to have robots build huge solar shields in orbit, or have robots build huge dikes around our coastal cities (we reclaimed thousand of acres of land from the oceans in the middle ages - we can't do that in the 21st century?), or have giant naval cannons fire explosive shells full of light block aerosols into the upper atmosphere, or, or, or ...
There are so many ideas that aren't 50 years out - let alone centuries out - that can solve these problems.
I think that it's a truism that different countries have different default outlooks. It can't be taken too far, but there are archetypes. Russians are darkly amused by the inevitability of defeat. Americans are gee-whiz let's change the world neophytes. Germans are prone to being a bit dour, etc.
Stross seems to be in the mainstream of British / Scottish cultural thought (at least as it's been revealed to be by fiction, both science fiction and mainstream). Stereotypical American apocalyptic fiction, I suggest, is about raging against the problem and striving to overcome it...and British apocalyptic fiction is more often than not about coming to terms with it.
tl;dr I find Stross' futurism uninteresting and wrong-headed because he seems to find reasons to justify his slightly depressive theres-nothing-we-can-do attitude.
If your nation consists of 1/6th of the world's population, you bear 1/6th the burden of the global warming triggered by your fossil fuel use, but get 100% of the energy output from your fossil fuel use. Conversely, if you unilaterally decide to build a giant shade for the earth, you foot 100% of the bill yet only receive 1/6th of the overall benefits.
Europe changed when explorers "discovered" the new world. Saying you are only going to focus on "this planet" is like saying I am only going to focus on the "old world" when talking about earth 500 years ago.
In my mind the rest of the article is pointless because the author is using the old world way of thinking about this planet.
The fact is the exploration of space is very similar as what happened 520 years ago. What happens when the price of getting to orbit drops significantly because of reusable rockets? Already there are companies that are planning on mining astroids. Saying that this is not going to effect earth in a major way is not really looking at where earth will be in 2512.
Space exploration is going to define the next 500 years of humanity and of this planet just as exploration of the new world defined the last 500 years.
http://www.antipope.org/charlie/blog-static/2007/06/the_high...
"Sea levels will have risen by at least one, and possibly more than ten metres worldwide."
"Fission: will be in widespread safe use or completely taboo."
The ease and volume of communication is bound to increase. Perhaps we communicate through technological telepathy, with anyone we want to. We share thoughts and senses with groups of people and solve problems by adding more brain power. The Mythical Man Month is no longer mythical. Learning and "news" become instant. Communication is probably faster than the speed of light.
Physical objects are only slightly constrained to their form and location. They can be transformed and moved almost as easily as energy can. Having something only requires thought and currency.