Wow. This is some dope research. I'm blown away. (I've curated this post.)
I have no idea how you guys came up with these areas to explore. "Let us attempt to track the size of ships in the 1800s". "Let us research the temperature at which superconduction worked in the 1900s". This is an impressive number of trends explored and data gathered, and a fascinating set of results for thinking about AI but also for understanding history and the world generally.
Regarding curating the post, I have to mention that very rarely does historical research like this ever get written in such a simple, concise and readable way, so thank you very much for that on top of the research itself.
And above all, I'll remember to look out for discontinuities when interacting with product features, objects that have size, or Isambard Kingdom Brunel.
IIRC we had a bounty out, to crowdsource suggestions for metrics and specific inventions to investigate. We also just thought of a bunch ourselves. In fact one major limitation of our research is that there are probably all sorts of selection biases in what we chose to investigate; it would be great to have a random sample instead of a brainstormed sample, because then we could say much more substantial things about the probability of discontinuities.
IMO Isambard Kingdom Brunel and Elon Musk seem pretty similar. For example, they both have weird names. I'd predict a heightened chance of discontinuities on metrics his companies are working on. Maybe also a heightened chance of something really big being built. :)
IMO Isambard Kingdom Brunel and Elon Musk seem pretty similar. For example, they both have weird names. I'd predict a heightened chance of discontinuities on metrics his companies are working on. Maybe also a heightened chance of something really big being built. :)
Are there any major recent discontinuities in the cost, range, or number of electric cars, cost or energy density of batteries, or cost of putting stuff into orbit?
I don't know; I haven't investigated. My guess is that the Falcon 9 is the most impressive of all the things Musk has done so far, but cost per kilogram to orbit is a weird metric because of how corrupt and ossified the industry is (other than SpaceX.) When companies like Boeing, ULA, etc. manage to lobby politicians to throw huge wads of cash at them for inferior products, and then SpaceX comes along and undercuts them with a superior product, who knows what the "real" costs-per-kilogram are? Both SpaceX and its competitors are probably charging substantially more than they need to.
Cost, range, and number of electric cars are rather artificial metrics-- I think measuring the cost, range, and number of cars in total would be much more in the spirit of the post, which haven't seen any surprising departures from trends. As for batteries, a ~15% decrease in cost per doubling in cumulative number of lithium-ion batteries produced combined with roughly exponential growth in the market has meant a smooth trend over the past few years: see this source.
I believe it's also easily checked that there's no significant discontinuity in cost to orbit. Starship could be promising, and Musk's goal is an extremely ambitious $2M/1000t to LEO, but even that is only 30 years or so on the current trend line.
On the contrary, the graph of launch costs you link seems to depict Falcon 9 as a 15-ish-year discontinuity in cost to orbit; I think you are misled by the projection, which is based on hypothetical future systems rather than on extrapolating from actual existing systems.
On the last point, I wonder if there might be a slight bias in general of history remembering people with distinctive names, or indeed other irrelevant characteristics. (Cf Robert Hooke's disputes with other scientists led to centuries of underestimation of his importance.)
Very interesting work indeed. A bunch of different observations:
The invention of the shipping container seems a likely candidate for a discontinuity in shipping speed, shipping costs and global trade. Though economic data on it is patchy, the go-to book on the subject is The Box by Marc Levinson.
Re invention of the telegraph, the book A Farewell to Alms by Gregory Clark accounts (pp. 305-7) via a series of clever inferences how from Roman times to 1800 the speed of long-distance travel of important information, regardless of method, was constant at 1 mph. This increased slightly in the first half of the 19th century, until the discontinuity from the telegraph. The book has lots of other data on historical innovation that may well be useful to you.
Re product features, and this recent LessWrong article (which no doubt you've seen) about the crucial difference between a prototype and a practical invention, I repeat my comment there that a high-quality implementation, e.g. usability & user-friendliness, rather than specific features often seems to be the crucial breakthrough. As shown by Apple: various inventions of theirs - the Apple Mac, iPod, smartphone, iPad - had little innovation as such. Desktop computers, GUIs, mice; digital music players; mobile phones, personal digital assistants; touch screens, tablet computers - these all already existed. But in each case Apple's breakthrough was to take them from being commercial but mediocre implementations, to very good implementations. And only when that happened did mass adoption occur, which is a crucial step in the impact of the invention.
Finally, I should make the obvious remark that though looking at the history of past inventions is very interesting, applying this to the future, particularly to AI, would be an extrapolation, which may or may not be valid at all, particularly if superhuman AGI is a quite different phenomenon from any previous invention (which it may well be).
It would be interesting to find some more discontinuities that are unrelated to Western Civilization.
For example, what about Zheng He's treasure voyages or the Great Wall of China? Or Mesoamerican civilizations?
Could you systematically contact relevant historians to farm this work out?
American civilizations are more recent than one might expect - the big iconic pyramids at Chichen Itza date from ~1000 CE. Plus, a lot of the historical data is vague or hard to get at - not just because of spanish missionaries, but also because a lot of the big North American civilizations left monuments in the form of huge earthworks, not stone, and their written records, if they existed, are lost.
There are definitely upheavals and discontinuities in the archaeological record (the one that really comes to mind is the introduction of corn to north america), but I'm not so sure about our ability to reconstruct nontrivial engineering-type metrics.
I agree that it would be interesting to look at evidence from further in the past or from non-Western progress.
Unfortunately, we found researching progress from before roughly 1700-1800 (and sometimes even later) to often be quite difficult. Most sources are vague, disagree with each other, or have clear signs of unreliability. Even when we have good accounts of what the state of the art was at some particular time, it was difficult to establish a progress trend leading up to it.
You're probably right that professional historians would be good at sorting some of these problems out. Usually when we did contact subject matter experts during the investigation, they could at help us to reality check out findings, but we did not try to get them to actually do work for us.
You should definitely try harder to connect with academic historians. They justify their existence by telling us they can help us learn from the past - this is a golden opportunity for it!
I was surprised that I had misremembered this post significantly. Over the past two years somehow my brain summarized this as "discontinuities barely happen at all, maybe nukes, and even that's questionable." I'm not sure where I got that impression.
Looking back here I am surprised at the number of discontinuities discovered, even if there are weird sampling issues of what trendlines got selected to investigate.
Rereading this, I'm excited by... the sort of sheer amount of details here. I like that there's a bunch of different domains being explored, which helps fill in a mosaic of how the broader world fits together.
It's an interesting question how much any of this should directly bear on AI timeline forecasts. The more recent debates between Eliezer and Paul dig into some differences into how to apply this. Is AI going to be like past technological jumps, or an entirely new one?
I appreciate Katja et all flagging various potential issues with the methodology in the original post, and noting some possible other questions you could research. If I had infinite researchers I'd probably still want those questions explored, but I'm not sure how many of current researchers I'd be excited to delve into those followup questions. I feel like the approach of "investigate past trends" has passed the 80/20 point of informing our AI timelines, and I'd probably prefer those researchers to orient to new questions that illuminate different facets of the AI strategic landscape.
I feel like the approach of "investigate past trends" has passed the 80/20 point of informing our AI timelines, and I'd probably prefer those researchers to orient to new questions that illuminate different facets of the AI strategic landscape.
I specialise in researching this topic. My impression is that barely anyone has looked at past technological trends, neither in academia nor in the LW/EA community. I am generally quite excited about more people looking into this space, because it seems neglected and the kind of topic where EA/LW type of people have a significant edge.
One thing that jumped out at me when reading this is that you were counting something as a discontinuity (a relative rate of change) by looking at how many years it jumped ahead (an absolute rate of change). This effectively rules out most recent technologies because the rate of technological progress is already quite high, so you'd have a much harder time jumping 100 years ahead of schedule now than you would have in the past.
I would think that a better metric would be to use some measure of general technological progress as a a base (the x-axis) instead of absolute number of years. I strongly suspect that you would find quite a few more discontinuities this way which were otherwise ruled out because they didn't "jump far enough ahead". For example, I suspect that AlexNet would be a discontinuity on this metric.
What were the 38 trends you studied? How did you select them? How confident are you that the other 28 don't have discontinuities that you missed?
How about paying attention to discontinuous progress in tasks that are related to DL? It is very easy to track with https://paperswithcode.com/sota . And https://sotabench.com/ is showing diminishing returns.
Such a great article! I thought the AlexNet that led to the recent AI break through could be viewed as a discontinuity too. The background and some statistics result are well summarized in below link.
https://qz.com/1034972/the-data-that-changed-the-direction-of-ai-research-and-possibly-the-world/
With planes and ICBMs crossing the ocean, there seemed to be a pattern where incremental progress had to pass a threshold on some dimension before incremental progress on a dimension of interest mattered, which gave rise to discontinuity. Is that a common pattern? (Is that a correct way to think about what was going on?)
This reminds me of Clayten Christensen's idea of disruptive innovation, where a new approach to a product may at first only be suitable for niche use cases, but has a higher growth rate of improvement than the traditional approach, and so eventually crosses some threshold and dominates the market.
(Disruptive innovations wouldn't necessarily produce discontinuous progress, but the underlying phenomenon of different rates of progress for different approaches to a problem seems to be the same as what's observed here.)
Interested to see a historical analysis of luminous efficacy. Spans 3 orders of magnitude, similar timeframe to other topics covered, and also like other topics here includes many sequential innovations as opposed to mere iteration on a particular technology.
Some questions to ask yourselves. I don't want answers to them, but I think you need solid answers to them for yourselves.
1. What negative discontinuities did you find - situations where a trend was held in check for a long period, before resuming? What insights do you draw from them?
2. Why use the same timescale for all activities?
3. Why the binary threshold for significance?
4. Science is all about finding good questions to ask. I have a feeling that this isn't a very good question, nor is the object of study well defined. Why do you believe that this question/this cabinet of curiosities tells you something useful?
https://en.wikipedia.org/wiki/Optical_telegraph preexisted the electric telegraph for speed of information over land. (Although it has some related systems, such as heliographs.)
I'd guess materials science as a field with several discontinuous leaps. Bessemer process, duraluminium, carbon fiber reinforced plastics: I think these are the most famous candidates. (It's hard to put it into metrics, but nearly all non-immobile things were structurally built out of wood until Bessemer/Martin steel came around.)
Rocketry is intimately related to nuclear bombs. The impetus to develop it came from the fact that now a small payload could destroy a city. (In WW2, a V2 occasionally leveled an apartment block or two. This is not a performance that justifies investing in an ICBM.) The early space race was largely a demonstration of this capability, as a rocket capable of accelerating a multiple-ton payload into near-circular orbit required to hit the other side of the earth is necessarily capable of accelerating a few-hundred-kg payload into low earth orbit, and vice versa.
https://en.wikipedia.org/wiki/Duga_radar for power used in an active sensor (mostly searchlights and radars)?
I. The search for discontinuities
We’ve been looking for historic cases of discontinuously fast technological progress, to help with reasoning about the likelihood and consequences of abrupt progress in AI capabilities. We recently finished expanding this investigation to 37 technological trends.1 This blog post is a quick update on our findings. See the main page on the research and its outgoing links for more details.
We found ten events in history that abruptly and clearly contributed more to progress on some technological metric than another century would have seen on the previous trend.2 Or as we say, we found ten events that produced ‘large’, ‘robust’ ‘discontinuities’.
Another five events caused robust discontinuities of between ten and a hundred years (‘moderate robust discontinuities’). And 48 more events caused some trend to depart from our best guess linear or exponential extrapolation of its past progress by at least ten years (and often a hundred), but did so in the context of such unclear past trends that this did not seem clearly remarkable.3 I call all of these departures ‘discontinuities’, and distinguish those that are clearly outside plausible extrapolations of the past trend, according to my judgment, as ‘robust discontinuities’.4
Much of the data involved in this project seems at least somewhat unreliable, and the methods involve many judgments, and much ignoring of minor issues. So I would not be surprised if more effort could produce numerous small changes. However I expect the broad outlines to be correct.5
II. The discontinuities
Large robust discontinuities
Here is a quick list of the robust 100-year discontinuous events, which I’ll describe in more detail beneath:
The Pyramid of Djoser, 2650BC
Discontinuity in structure height trends6
The Pyramid of Djoser is considered to be ‘the earliest colossal stone structure’ in Egypt. According to Wikipedia’s data, it took seven thousand years for the tallest structures to go from five to thirteen meters tall7 and then suddenly the Egyptian pyramids shot up to a height of 146.5m over about a hundred years and five successively tallest pyramids.
The first of these five is the Pyramid of Djoser, standing 62.5m tall. The second one—Meidum Pyramid—is also a large discontinuity in structure height trends by our calculation, but I judge it not robust, since it is fairly unclear what the continuation of the trend should be after the first discontinuity. As is common, the more basic thing going on seems to be a change in the growth rate, and the discontinuity of the Pyramid of Djoser is just the start of it.
Strangely, after this spurt of progress, humanity built nothing taller than the tallest pyramid for nearly four thousand years—until Lincoln Cathedral in 1311—and nothing more than twenty percent taller than it until the Eiffel Tower in 1889.
The SS Great Eastern
Discontinuity in ship size, measured in ‘builder’s old measurement’8 or in displacement.
The SS Great Eastern was a freakishly large ship. For instance, it seems to have weighed about five times as much as any previous ship. As far as I can tell, the reason it existed is that Isambard Kingdom Brunell thought it would be good. Brunell was a 19th Century engineering hero, rated #2 greatest Briton of all time in a 2002 BBC poll, who according to Wikipedia, ‘revolutionised public transport and modern engineering’ and built ‘dockyards, the Great Western Railway (GWR), a series of steamships including the first propeller-driven transatlantic steamship, and numerous important bridges and tunnels’.
The experimental giant sailing steamship idea doesn’t seem to have gone well. The Great Eastern apparently never had its cargo holds filled, and ran at a deficit for years before being sold and used for laying the second telegraph cable (another source of large discontinuity—see below).9 It was designed for transporting passengers to the Far East, but there was never the demand.10 It was purportedly rumored to be ‘cursed’, and suffered various ill fortune. On its maiden voyage a boiler exploded, throwing one of the funnels into the air and killing six people.11 Later it hit a rock and got a 9-foot gash, which seems to have been hard to fix because the ship was too big for standard repair methods.12
We don’t have a whole trend for largest ships, so are using British Royal Navy ship of the line size trends as a proxy against which to compare the Great Eastern.13 This gives us discontinuities of around 400 years in both displacement and tonnage (BOM). [Added May 10: Nuño Sempere has also investigated the Great Eastern as a discontinuity, and has some nice figures comparing it to passenger and sailing vessel trends.]
However that is assuming we expect ship size to increase either linearly or exponentially (our usual expectation). But looking at the ship of the line trends, both displacement and cargo capacity (measured in tonnage, BOM) seemed to grow at something closer to a hyperbolic curve for some reason—apparently accelerating toward an asymptote in the late 1860s. If we had expected progress to continue this way throughout, then neither trend had any discontinuities, instead of eight or eleven of them. And supposing that overall ship size follows the same hyperbola as the military ship trends, then the Great Eastern’s discontinuities go from around 400 years to roughly 11 or 13 years. Which doesn’t sound big, but since this was about that many years before of the asymptote of the hyperbola at which point arbitrarily large ships were theoretically expected, the discontinuities couldn’t have been much bigger.
Our data ended for some reason just around the apparently impending ship size singularity of the late 1860s. But my impression is that not much happened for a while—it apparently took forty years for a ship larger than the Great Eastern to be built, on many measures.
I am unsure what to make of the apparently erroneous and unforced investment in the most absurdly enormous ship happening within a decade or two of the point at which trend extrapolation appears to have suggested arbitrarily large ships. Was Brunell aware of the trend? Did the forces that produced the rest of the trend likewise try to send all the players in the ship-construction economy up the asymptote, where they crashed into some yet unmet constraint? It is at least nice to have more examples of what happens when singularities are reached in the human world.
The first transatlantic telegraph
Discontinuity in speed of sending a 140 character message across the Atlantic Ocean
Until 1858, the fastest way to get a message from New York to London was by ship, and the fastest ships took over a week14. Telegraph was used earlier on land, but running it between continents was quite an undertaking. The effort to lay the a transatlantic cable failed numerous times before it became ongoingly functional.15 One of those times though, it worked for about a month, and messages were sent.16 There were celebrations in the streets.
The telegraph could send a 98 word message in a mere 16 hours. For a message of more than about 1400 words, it would actually have been faster to send it by ship (supposing you already had it written down). So this was a big discontinuity for short messages, but not necessarily any progress at all for longer ones.
The second transatlantic telegraph
Discontinuity in speed of sending a 140 character message across the Atlantic Ocean
After the first working transatlantic telegraph cable (see above) failed in 1858, it was another eight years before the second working cable was finished. Most of that delay was apparently for lack of support.17 and the final year seems to have been because the cable broke and the end was lost at sea after over a thousand miles had been laid, leaving the ship to return home and a new company to be established before the next try.18 Whereas it sounds like it took less than a day to go from the ship carrying the cable arriving in port, and the sending of telegraphs.
At a glance, on Wikipedia’s telling, it sounds as though the perseverance of one person—Cyrus West Field—might have affected when fast transatlantic communication appeared by years. He seems to have led all five efforts, supplied substantial money himself, and ongoingly fundraised and formed new companies, even amidst a broader lack of enthusiasm after initial failures. (He was also given a congressional gold medal for establishing the transatlantic telegraph cable, suggesting the US congress also has this impression.) His actions wouldn’t have affected how much of a discontinuity either telegraph was by much, but it is interesting if such a large development in a seemingly important area might have been accelerated much by a single person.
The second telegraph cable was laid by the Great Eastern, the discontinuously large ship of two sections ago. Is there some reason for these two big discontinuities to be connected? For instance, did one somehow cause the other? That doesn’t seem plausible. The main way I can think of that the transatlantic telegraph could have caused the Great Eastern‘s size would be if the economic benefits of being able to lay cable were anticipated and effectively subsidized the ship. I haven’t heard of this being an intended use for the Great Eastern. And given that the first transatlantic telegraph was not laid by the Great Eastern, it seems unlikely that such a massive ship was strictly needed for the success of a second one at around that time, though the second cable used was apparently around twice as heavy as the first. Another possibility is that some other common factor made large discontinuities more possible. For instance, perhaps it was an unusually feasible time and place for solitary technological dreamers to carry out ambitious and economically adventurous projects.
The first non-stop transatlantic flight
Discontinuity in both speed of passenger travel across the Atlantic Ocean and speed of military payload travel across the Atlantic Ocean
Ships were the fastest way to cross the Atlantic Ocean until the end of World War I. Passenger liners had been getting incrementally faster for about eighty years, and the fastest regular passenger liner was given a special title, ‘Blue Riband‘. Powered heavier-than-air flight got started in 1903, but at first planes only traveled hundreds of feet, and it took time to expand that to the 1600 or so miles needed to cross the Atlantic in one hop.19
The first non-stop transatlantic flight was made shortly after the end of WWI, in 1919. The Daily Mail had offered a large cash prize, on hold during the war, and with the resumption of peace, a slew of competitors prepared to fly. Alcock and Brown were the first to do it successfully, in a modified bomber plane, taking around 16 hours, for an average speed around four times faster than the Blue Riband.
One might expect discontinuities to be especially likely in a metric like ‘speed to cross the Atlantic’, which involves a sharp threshold on a non-speed axis for inclusion in the speed contest. For instance if planes incrementally improved on speed and range (and cost and comfort) every year, but couldn’t usefully cross the ocean at all until their range reached 1600 miles, then decades of incremental speed improvements could all hit the transatlantic speed record at once, when the range reaches that number.
Is this what happened? It looks like it. The Wright Flyer apparently had a maximum speed of 30mph. That’s about the record average ocean liner speed in 1909. So if the Wright Flyer had had the range to cross the Atlantic in 1903 at that speed, it would have been about six years ahead of the ship speed trend and wouldn’t have registered as a substantial discontinuity. 20 But because it didn’t have the range, and because the speed of planes was growing faster than that of ships, in 1919 when planes could at last fly thousands of miles, they were way ahead of ships.
The George Washington Bridge
Discontinuity in longest bridge span
A bridge ‘span‘ is the distance between two intermediate supports in a bridge. The history of bridge span length is not very smooth, and so arguably full of discontinuities, but the only bridge span that seems clearly way out of distribution to me is the main span of the George Washington Bridge. (See below.)
I’m not sure what made it so discontinuously long, but it is notably also the world’s busiest motor vehicle bridge (as of 2016), connecting New York City with New Jersey, so one can imagine that it was a very unusually worthwhile expanse of water to cross. Another notable feature of it was that it was much thinner relative to its length than long suspension bridges normally were, and lacked the usual ‘trusses’, based on a new theory of bridge design.21
Nuclear weapons
Discontinuity in relative effectiveness of explosives
The ‘relative effectiveness factor‘ of an explosive is how much TNT you would need to do the same job.22 Pre-nuclear explosives had traversed the range of relative effectiveness factors from around 0.5 to 2 over about a thousand years, when in 1945 the first nuclear weapons came in at a relative effectiveness of around 450023.
A few characteristics of nuclear weapons that could relate to their discontinuousness:
I discussed whether and how these things might be related to the discontinuity in 2015 here (see Gwern’s comment) and here.
The Paris Gun
Discontinuity in altitude reached by man-made means
The Paris Gun was the largest artillery gun in WWI, used by the Germans to bomb Paris from 75 miles away. It could shoot 25 miles into the air, whereas the previous record we know of was around 1 mile into the air (also shot by a German gun).24
I don’t have much idea why the Paris Gun traveled so much higher than previous weapons. Wikipedia suggests that its goals were psychological rather than physically effective warfare:
This might explain an unusual trade-off of distance (and therefore altitude) against features like accuracy and destructive ability. On this story, building a weapon to shoot a projectile 25 miles into the air had been feasible for some time, but wasn’t worth it. This highlights the more general possibility that the altitude trend was perhaps more driven by the vagaries of demand for different tangentially-altitude-related ends than by technological progress.
The German military apparently dismantled the Paris Guns before departing, and did not comply with a Treaty of Versailles requirement to turn over a complete gun to the Allies, so the guns’ capabilities are not known with certainty. However it sounds like the shells were clearly observed in Paris, and the relevant gun was clearly observed around 70 miles away, so the range is probably not ambiguous, and the altitude reached by a projectile is closely related to the range. So uncertainty around the gun probably doesn’t affect our conclusions.
The first intercontinental ballistic missiles (ICBMs)
Discontinuity in average speed of military payload crossing the Atlantic Ocean
For most of history, the fastest way to send a military payload across the Atlantic Ocean was to put it on a boat or plane, much like a human passenger. So the maximum speed of sending a military payload across the Atlantic Ocean followed the analogous passenger travel trend. However in August 1957, the two abruptly diverged with the first successful test of an intercontinental ballistic missile (ICBM)—the Russian R-7 Semyorka. Early ICBMs traveled at around 11 thousand miles per hour, taking the minimum time to send a military payload between Moscow and New York for instance from around 14 hours to around 24 minutes.25
A ‘ballistic‘ missile is unpowered during most of its flight, and so follows a ballistic trajectory—the path of anything thrown into the air. Interestingly, this means that in order to go far enough to traverse the Atlantic, it has to be going a certain speed. Ignoring the curvature of the Earth or friction, this would be about 7000 knots for the shortest transatlantic distance—70% of its actual speed, and enough to be hundreds of years of discontinuity in the late 50s.26 So assuming ballistic missiles crossed the ocean when they did, they had to produce a large discontinuity in the speed trend.
Does this mean the ICBM was required to be a large discontinuity? No—there would be no discontinuity if rockets were improving in line with planes, and so transatlantic rockets were developed later, or ICBM-speed planes earlier. But it means that even if the trends for rocket distance and speed are incremental and start from irrelevantly low numbers, if they have a faster rate of growth than planes, and the threshold in distance required implies a speed way above the current record, then a large discontinuity must happen
This situation also means that you could plausibly have predicted the discontinuity ahead of time, if you were watching the trends. Seeing the rocket speed trend traveling upward faster than the plane speed trend, you could forecast that when it hit a speed that implied an intercontinental range, intercontinental weapons delivery speed would jump upward.
YBa2Cu3O7 as a superconductor
Discontinuity in warmest temperature of superconduction
When an ordinary material conducts electricity, it has some resistance (or opposition to the flow of electrons) which takes energy to overcome. The resistance can be gradually lowered by cooling the material down. For some materials though, there is a temperature threshold below which their resistance abruptly drops to zero, meaning for instance that electricity can flow through them indefinitely with no input of energy. These are ‘superconductors‘.
Superconductors were discovered in 1911. The first one observed, mercury, could superconduct below 4.2 Kelvin. From then on, more superconductors were discovered, and the warmest observed temperatures of superconduction gradually grew. In 1957, BCS theory was developed to explain the phenomenon (winning its authors a Nobel Prize), and was understood to rule out superconduction above temperatures of around 30K. But in 1986 a new superconductor was found with a threshold temperature around 30K, and composed of a surprising material: a ‘ceramic’ involving oxygen rather than an alloy.27 This also won a Nobel Prize, and instigated a rapid series of discoveries in similar materials—’cuprates‘—which shot the highest threshold temperatures to around 125 K by 1988 (before continued upward).
The first of the cuprates, LaBaCuO4, seems mostly surprising for theoretical reasons, rather than being radically above the temperature trend.28 The big jump came the following year, from YBa2Cu3O7, with its threshold at over 90 K.29
This seems like a striking instance of the story where the new technology doesn’t necessarily cause a jump so much as a new rate of progress. I wonder if there was a good reason for the least surprising cuprate to be discovered first. My guess is that there were many unsurprising ones, and substances are only famous if they were discovered before more exciting substances.
It is interesting to me that this is associated with a substantial update in very basic science, much like nuclear weapons. I’m not sure if that makes basic science updates ripe for discontinuity, or if there are just enough of them that some would show up in this list. (Though glancing at this list suggests to me that there were about 70 at this level in the 20th Century, and probably many fewer immediately involving a new capability rather than e.g. an increased understanding of pulsars. Penicillin also makes that list though, and we didn’t find any discontinuities it caused.)
Moderate robust discontinuities (10-100 years of extra progress):
The 10-100 year discontinuous events were:
Other places we looked
Here are places we didn’t find robust discontinuities32) – follow the links to read about any in detail:
III. Some observations
Prevalence of discontinuities
Some observations on the overall prevalence of discontinuities:
This all suggests that discontinuities, and large discontinuities in particular, are more common than I thought previously (though still not that common). One reason for this change is that I was treating difficulty of finding good cases of discontinuous progress as more informative than I do now. I initially thought there weren’t many around because suggested discontinuities often turned out not to be discontinuous, and there weren’t a huge number of promising suggestions. However we later got more good suggestions, and found many discontinuities where we weren’t necessarily looking for them. So I’m inclined to think there are a few around, but our efforts at seeking them out specifically just weren’t very effective. Another reason for a larger number now is that our more systematic methods now turn up many cases that don’t look very remarkable to the naked eye (those I have called non-robust), which we did not necessarily notice earlier. How important these are is less clear.
Discontinuities go with changes in the growth rate
It looks like discontinuities are often associated with changes in the growth rate. At a glance, 15 of the 38 trends had a relatively sharp change in their rate of progress at least once in their history. These changes in the growth rate very often coincided with discontinuities—in fourteen of the fifteen trends, at least one sharp change coincided with one of the discontinuities.35 If this is a real relationship, it means that if you see a discontinuity, there is a much heightened chance of further fast progress coming up. This seems important, but is a quick observation and should probably be checked and investigated further if we wanted to rely on it.
Where do we see discontinuities?
Among these case studies, when is a development more likely to produce a discontinuity in a trend?36 Some observations so far, based on the broader class including non-robust discontinuities, except where noted:
If we loosely divide trends into ‘technical’ (to do with scientific results e.g. highest temperature of a superconductor), ‘product’ (to do with individual objects meant for use e.g. cotton ginned by a cotton gin, height of building), ‘industry’ (to do with entire industries e.g. books produced in the UK) or ‘societal’ (to do with features of non-industry society e.g. syphilis deaths in the US), then ‘product’ trends saw around four times as many discontinuities as technical trends, and the other two are too small to say much. (Product trends are less than twice as likely to have any discontinuities, so the difference was largely in how many discontinuities they have per trend.)
If we loosely divide trends into ‘features’ (things that are good but not the main point of the activity), ‘performance proxies’ (things that are roughly the point of the activity) and ‘value proxies’ (things that roughly measure the net value of the activity, accounting for its costs as well as performance), then features were more discontinuous than performance proxies.37
(Unsurprisingly, given the above.) Overall, the 16 ‘product features’ we looked at had 4.6 discontinuities per trend on average, whereas the 22 other metrics had 0.7 discontinuities per trend on average (2 vs. 0.3 for large discontinuities).38 ‘Product features’ include for instance sizes of ships and fire rate of guns, whereas non-product features include total books produced per century, syphilis deaths in the US, and highest temperature of known superconductors.
Most of the discontinuities we found happened after 1800. This could be a measurement effect, since much more recent data is available, and if we can’t find enough data to be confident, we are not deeming things discontinuities. For instance, the two obscure cotton gins before Whitney’s famous 1793 one that look responsible for huge jumps according to our sparse and untrustworthy 1700s data. The concentration of discontinuities since 1800 might also be related to progress speeding up in the last couple of centuries. Interestingly, since 1800 the rate of discontinuities doesn’t seem to be obviously increasing. For instance, seven of nine robust discontinuous events since 1900 happened by 1960.39
Four of our ten robust discontinuous events of over a hundred years came from the three transatlantic travel speed trends we considered. They are also high on non-robust discontinuities.
To measure discontinuities, we had to extrapolate past progress. We did this at each point, based on what the curve looked like so far. Some trends we consistently called exponential, some consistently linear, and some sometimes seemed linear and sometimes exponential. The ten in this third lot all had discontinuities, whereas the 20 that consistently looked either exponential or linear were about half as likely to have discontinuities.40
‘Object size’ trends had over five discontinuities per trend, compared to the average of around 2 across all trends.
I mentioned Brunel above in connection with the Great Eastern. As well as designing that discontinuously large ship, which lay one of the discontinuously fast transatlantic telegraph cables, he designed the non-robustly discontinuous earlier ship Warrior.
I feel like there are other obvious patterns that I’m missing. Some other semi-obvious patterns that I’m noticing but don’t have time to actually check now, I am putting in the next section.
More things to observe
There are lots of other interesting things to ask about this kind of data, in particular regarding what kinds of things tend to see jumps. Here are some questions that we might answer in future, or which we welcome you to try to answer (and hope our data helps with):
IV. Summary
Notes