Why risking nuclear war should be a war crime

Nov 19, JDN 2458078

“What is the value of a human life?” is a notoriously difficult question, probably because people keep trying to answer it in terms of dollars, and it rightfully offends our moral sensibilities to do so. We shouldn’t be valuing people in terms of dollars—we should be valuing dollars in terms of their benefits to people.

So let me ask a simpler question: Does the value of an individual human life increase, decrease, or stay the same, as we increase the number of people in the world?

A case can be made that it should stay the same: Why should my value as a person depend upon how many other people there are? Everything that I am, I still am, whether there are a billion other people or a thousand.

But in fact I think the correct answer is that it decreases. This is for two reasons: First, anything that I can do is less valuable if there are other people who can do it better. This is true whether we’re talking about writing blog posts or ending world hunger. Second, and most importantly, if the number of humans in the world gets small enough, we begin to face danger of total permanent extinction.

If the value of a human life is constant, then 1,000 deaths is equally bad whether it happens in a population of 10,000 or a population of 10 billion. That doesn’t seem right, does it? It seems more reasonable to say that losing ten percent should have a roughly constant effect; in that case losing 1,000 people in a population of 10,000 is equally bad as losing 1 billion in a population of 10 billion. If that seems too strong, we could choose some value in between, and say perhaps that losing 1,000 out of 10,000 is equally bad as losing 1 million out of 1 billion. This would mean that the value of 1 person’s life today is about 1/1,000 of what it was immediately after the Toba Event.

Of course, with such uncertainty, perhaps it’s safest to assume constant value. This seems the fairest, and it is certainly a reasonable approximation.

In any case, I think it should be obvious that the inherent value of a human life does not increase as you add more human lives. Losing 1,000 people out of a population of 7 billion is not worse than losing 1,000 people out of a population of 10,000. That way lies nonsense.

Yet if we agree that the value of a human life is not increasing, this has a very important counter-intuitive consequence: It means that increasing the risk of a global catastrophe is at least as bad as causing a proportional number of deaths. Specifically, it implies that a 1% risk of global nuclear war is worse than killing 10 million people outright.

The calculation is simple: If the value of a human life is a constant V, then the expected utility (admittedly, expected utility theory has its flaws) from killing 10 million people is -10 million V. But the expected utility from a 1% risk of global nuclear war is 1% times -V times the expected number of deaths from such a nuclear war—and I think even 2 billion is a conservative estimate. (0.01)(-2 billion) V = -20 million V.

This probably sounds too abstract, or even cold, so let me put it another way. Suppose we had the choice between two worlds, and these were the only worlds we could choose from. In world A, there are 100 leaders who each make choices that result in 10 million deaths. In world B, there are 100 leaders who each make choices that result in a 1% chance of nuclear war. Which world should we choose?

The choice is a terrible one, to be sure.

In world A, 1 billion people die.

Yet what happens in world B?

If the risks are independent, we can’t just multiply by 100 to get a guarantee of nuclear war. The actual probability is 1-(1-0.01)^100 = 63%. Yet even so, (0.63)(2 billion) = 1.26 billion. The expected number of deaths is higher in world B. Indeed, the most likely scenario is that 2 billion people die.

Yet this is probably too conservative. The risks are most likely positively correlated; two world leaders who each take a 1% chance of nuclear war probably do so in response to one another. Therefore maybe adding up the chances isn’t actually so unreasonable—for all practical intents and purposes, we may be best off considering nuclear war in world B as guaranteed to happen. In that case, world B is even worse.

And that is all assuming that the nuclear war is relatively contained. Major cities are hit, then a peace treaty is signed, and we manage to rebuild human civilization more or less as it was. This is what most experts on the issue believe would happen; but I for one am not so sure. The nuclear winter and total collapse of institutions and infrastructure could result in a global apocalypse that would result in human extinctionnot 2 billion deaths but 7 billion, and an end to all of humanity’s projects once and forever This is the kind of outcome we should be prepared to do almost anything to prevent.

What does this imply for global policy? It means that we should be far more aggressive in punishing any action that seems to bring the world closer to nuclear war. Even tiny increases in risk, of the sort that would ordinarily be considered negligible, are as bad as murder. A measurably large increase is as bad as genocide.

Of course, in practice, we have to be able to measure something in order to punish it. We can’t have politicians imprisoned over 0.000001% chances of nuclear war, because such a chance is so tiny that there would be no way to attain even reasonable certainty that such a change had even occurred, much less who was responsible.

Even for very large chances—and in this context, 1% is very large—it would be highly problematic to directly penalize increasing the probability, as we have no consistent, fair, objective measure of that probability.

Therefore in practice what I think we must do is severely and mercilessly penalize certain types of actions that would be reasonably expected to increase the probability of catastrophic nuclear war.

If we had the chance to start over from the Manhattan Project, maybe simply building a nuclear weapon should be considered a war crime. But at this point, nuclear proliferation has already proceeded far enough that this is no longer a viable option. At least the US and Russia for the time being seem poised to maintain their nuclear arsenals, and in fact it’s probably better for them to keep maintaining and updating them rather than leaving decades-old ICBMs to rot.

What can we do instead?

First, we probably need to penalize speech that would tend to incite war between nuclear powers. Normally I am fiercely opposed to restrictions on speech, but this is nuclear war we’re talking about. We can’t take any chances on this one. If there is even a slight chance that a leader’s rhetoric might trigger a nuclear conflict, they should be censored, punished, and probably even imprisoned. Making even a veiled threat of nuclear war is like pointing a gun at someone’s head and threatening to shoot them—only the gun is pointed at everyone’s head simultaneously. This isn’t just yelling “fire” in a crowded theater; it’s literally threatening to burn down every theater in the world at once.

Such a regulation must be designed to allow speech that is necessary for diplomatic negotiations, as conflicts will invariably arise between any two countries. We need to find a way to draw the line so that it’s possible for a US President to criticize Russia’s intervention in the Ukraine or for a Chinese President to challenge US trade policy, without being accused of inciting war between nuclear powers. But one thing is quite clear: Wherever we draw that line, President Trump’s statement about “fire and fury” definitely crosses it. This is a direct threat of nuclear war, and it should be considered a war crime. That reason by itself—let alone his web of Russian entanglements and violations of the Emoluments Clause—should be sufficient to not only have Trump removed from office, but to have him tried at the Hague. Impulsiveness and incompetence are no excuse when weapons of mass destruction are involved.

Second, any nuclear policy that would tend to increase first-strike capability rather than second-strike capability should be considered a violation of international law. In case you are unfamiliar with such terms: First-strike capability consists of weapons such as ICBMs that are only viable to use as the opening salvo of an attack, because their launch sites can be easily located and targeted. Second-strike capability consists of weapons such as submarines that are more concealable, so it’s much more likely that they could wait for an attack to happen, confirm who was responsible and how much damage was done, and then retaliate afterward.
Even that retaliation would be difficult to justify: It’s effectively answering genocide with genocide, the ultimate expression of “an eye for an eye” writ large upon humanity’s future. I’ve previously written about my Credible Targeted Conventional Response strategy that makes it both more ethical and more credible to respond to a nuclear attack with a non-nuclear retaliation. But at least second-strike weapons are not inherently only functional at starting a nuclear war. A first-strike weapon can theoretically be fired in response to a surprise attack, but only before the attack hits you—which gives you literally minutes to decide the fate of the world, most likely with only the sketchiest of information upon which to base your decision. Second-strike weapons allow deliberation. They give us a chance to think carefully for a moment before we unleash irrevocable devastation.

All the launch codes should of course be randomized onetime pads for utmost security. But in addition to the launch codes themselves, I believe that anyone who wants to launch a nuclear weapon should be required to type, letter by letter (no copy-pasting), and then have the machine read aloud, Oppenheimer’s line about Shiva, “Now I am become Death, the destroyer of worlds.” Perhaps the passphrase should conclude with something like “I hereby sentence millions of innocent children to death by fire, and millions more to death by cancer.” I want it to be as salient as possible in the heads of every single soldier and technician just exactly how many innocent people they are killing. And if that means they won’t turn the key—so be it. (Indeed, I wouldn’t mind if every Hellfire missile required a passphrase of “By the authority vested in me by the United States of America, I hereby sentence you to death or dismemberment.” Somehow I think our drone strike numbers might go down. And don’t tell me they couldn’t; this isn’t like shooting a rifle in a firefight. These strikes are planned days in advance and specifically designed to be unpredictable by their targets.)

If everyone is going to have guns pointed at each other, at least in a second-strike world they’re wearing body armor and the first one to pull the trigger won’t automatically be the last one left standing.

Third, nuclear non-proliferation treaties need to be strengthened into disarmament treaties, with rapid but achievable timelines for disarmament of all nuclear weapons, starting with the nations that have the largest arsenals. Random inspections of the disarmament should be performed without warning on a frequent schedule. Any nation that is so much as a day late on their disarmament deadlines needs to have its leaders likewise hauled off to the Hague. If there is any doubt at all in your mind whether your government will meet its deadlines, you need to double your disarmament budget. And if your government is too corrupt or too bureaucratic to meet its deadlines even if they try, well, you’d better shape up fast. We’ll keep removing and imprisoning your leaders until you do. Once again, nothing can be left to chance.

We might want to maintain some small nuclear arsenal for the sole purpose of deflecting asteroids from colliding with the Earth. If so, that arsenal should be jointly owned and frequently inspected by both the United States and Russia—not just the nuclear superpowers, but also the only two nations with sufficient rocket launch capability in any case. The launch of the deflection missiles should require joint authorization from the presidents of both nations. But in fact nuclear weapons are probably not necessary for such a deflection; nuclear rockets would probably be a better option. Vaporizing the asteroid wouldn’t accomplish much, even if you could do it; what you actually want to do is impart as much sideways momentum as possible.

What I’m saying probably sounds extreme. It may even seem unjust or irrational. But look at those numbers again. Think carefully about the value of a human life. When we are talking about a risk of total human extinction, this is what rationality looks like. Zero tolerance for drug abuse or even terrorism is a ridiculous policy that does more harm than good. Zero tolerance for risk of nuclear war may be the only hope for humanity’s ongoing survival.

Throughout the vastness of the universe, there are probably billions of civilizations—I need only assume one civilization for every hundred galaxies. Of the civilizations that were unwilling to adopt zero tolerance policies on weapons of mass destruction and bear any cost, however unthinkable, to prevent their own extinction, there is almost boundless diversity, but they all have one thing in common: None of them will exist much longer. The only civilizations that last are the ones that refuse to tolerate weapons of mass destruction.

The Expanse gets the science right—including the economics

JDN 2457502

Despite constantly working on half a dozen projects at once (literally—preparing to start my PhD, writing this blog, working at my day job, editing a novel, preparing to submit a nonfiction book, writing another nonfiction book with three of my friends as co-authors, and creating a card game—that’s seven actually), I do occasionally find time to do things for fun. One I’ve been doing lately is catching up on The Expanse on DVR (I’m about halfway through the first season so far).

If you’re not familiar with The Expanse, it has been fairly aptly described as Battlestar Galactica meets Game of Thrones, though I think that particular comparison misrepresents the tone and attitudes of the series, because both BG and GoT are so dark and cynical (“It’s a nice day… for a… red wedding!”). I think “Star Trek meets Game of Thrones” might be better actually—the extreme idealism of Star Trek would cancel out the extreme cynicism of Game of Thrones, with the result being a complex mix of idealism and cynicism that more accurately reflects the real world (a world where Mahatma Gandhi and Adolf Hitler lived at the same time). That complex, nuanced world (or should I say worlds?) is where The Expanse takes place. ST is also more geopolitical than BG and The Expanse is nothing if not geopolitical.

But The Expanse is not just psychologically realistic—it is also scientifically and economically realistic. It may in fact be the hardest science fiction I have ever encountered, and is definitely the hardest science fiction I’ve seen in a television show. (There are a few books that might be slightly harder, as well as some movies based on them.)

The only major scientific inaccuracy I’ve been able to find so far is the use of sound effects in space, and actually even these can be interpreted as reflecting an omniscient narrator perspective that would hear any sounds that anyone would hear, regardless of what planet or ship they might be on. The sounds the audience hears all seem to be sounds that someone would hear—there’s simply no particular person who would hear all of them. When people are actually thrown into hard vacuum, we don’t hear them make any noise.

Like Firefly (and for once I think The Expanse might actually be good enough to deserve that comparison), there is no FTL, no aliens, no superhuman AI. Human beings are bound within our own solar system, and travel between planets takes weeks or months depending on your energy budget. They actually show holograms projecting the trajectory of various spacecraft and the trajectories actually make good sense in terms of orbital mechanics. Finally screenwriters had the courage to give us the terrifying suspense and inevitability of an incoming nuclear missile rounding a nearby asteroid and intercepting your trajectory, where you have minutes to think about it but not nearly enough delta-v to get out of its blast radius. That is what space combat will be like, if we ever have space combat (as awesome as it is to watch, I strongly hope that we will not ever actually do it). Unlike what Star Trek would have you believe, space is not a 19th century ocean.

They do have stealth in space—but it requires technology that even to them is highly advanced. Moreover it appears to only work for relatively short periods and seems most effective against civilian vessels that would likely lack state-of-the-art sensors, both of which make it a lot more plausible.

Computers are more advanced in the 2200s then they were in the 2000s, but not radically so, at most a million times faster, about what we gained since the 1980s. I’m guessing a smartphone in The Expanse runs at a few petaflops. Essentially they’re banking on Moore’s Law finally dying sometime in the mid 21st century, but then, so am I. Perhaps a bit harder to swallow is that no one has figured out good enough heuristics to match human cognition; but then, human cognition is very tightly optimized.

Spacecraft don’t have artificial gravity except for the thrust of their engines, and people float around as they should when ships are freefalling. They actually deal with the fact that Mars and Ceres have lower gravity than Earth, and the kinds of health problems that result from this. (One thing I do wish they’d done is had the Martian cruiser set a cruising acceleration of Mars-g—about 38% Earth-g—that would feel awkward and dizzying to their Earther captives. Instead they basically seem to assume that Martians still like to use Earth-g for space transit, but that does make some sense in terms of both human health and simply transit time.) It doesn’t seem like people move around quite awkwardly enough in the very low gravity of Ceres—which should be only about 3% Earth-g—but they do establish that electromagnetic boots are ubiquitous and that could account for most of this.

They fight primarily with nuclear missiles and kinetic weapons, and the damage done by nuclear missiles is appropriately reduced by the fact that vacuum doesn’t transmit shockwaves. (Nuclear missiles would still be quite damaging in space by releasing large amounts of wide-spectrum radiation; but they wouldn’t cause the total devastation they do within atmosphere.) Oddly they decided not to go with laser weapons as far as I can tell, which actually seems to me like they’ve underestimated advancement; laser weapons have a number of advantages that would be particularly useful in space, once we can actually make them affordable and reliable enough for widespread deployment. There could also be a three-tier system, where missiles are used at long range, railguns at medium range, and lasers at short range. (Yes, short range—the increased speed of lasers would be only slight compared to a good railgun, and would be more than offset by the effect of diffraction. At orbital distances, a laser is a shotgun.) Then again, it could well work out that railguns are just better—depending on how vessels are structured, puncturing their hulls with kinetic rounds could well be more useful than burning them up with infrared lasers.

But I think what really struck me about the realism of The Expanse is how it even makes the society realistic (in a way that, say, Firefly really doesn’t—we wanted a Western and we got a Western!).

The only major offworld colonies are Mars and Ceres, both of which seem to be fairly well-established, probably originally colonized as much as a century ago. Different societies have formed on each world; Earth has largely united under the United Nations (one of the lead characters is an undersecretary for the UN), but meanwhile Mars has split off into its own independent nation (“Martian” is now an ethnicity like “German” rather than meaning “extraterrestrial”), and the asteroid belt colonists, while formally still under Earth’s government, think of themselves as a different culture (“Belters”) and are seeking independence. There are some fairly obvious—but deftly managed rather than heavy-handed—parallels between the Belter independence movement and real-world independence movements, particularly Palestine (it’s hard not to think of the PLO when they talk about the OPA). Both Mars and the Belt have their own languages, while Earth’s languages have largely coalesced around English as the language of politics and commerce. (If the latter seems implausible, I remind you that the majority of the Internet and all international air traffic control are in English.) English is the world’s lingua franca (which is a really bizarre turn of phrase because it’s the Latin for French).

There is some of the conniving and murdering of Game of Thrones, but it is at a much more subdued level, and all of the major factions display both merits and flaws. There is no clear hero and no clear villain, just conflict and misunderstanding between a variety of human beings each with their own good and bad qualities. There does seem to be a sense that the most idealistic characters suffer for their idealism much as the Starks often do, but unlike the Starks they usually survive and learn from the experience. Indeed, some of the most cynical also seem to suffer for their cynicism—in the episode I just finished, the grizzled UN Colonel assumed the worst of his adversary and ended up branded “the butcher of Anderson Station”.

Cost of living on Ceres is extraordinarily high because of the limited living space (the apartments look a lot like the tiny studios of New York or San Francisco), and above all the need to constantly import air and water from Earth. A central plot point in the first episode is that a ship carrying comet ice—i.e., water—to Ceres is lost in a surprise attack by unknown adversaries with advanced technology, and the result is a deepening of an already dire water shortage, exacerbating the Belter’s craving for rebellion.

Air and water are recyclable, so it wouldn’t be that literally every drink and every breath needs to be supplied from outside—indeed that would clearly be cost-prohibitive. But recycling is never perfect, and Ceres also appears to have a growing population, both of which would require a constant input of new resources to sustain. It makes perfect sense that the most powerful people on Ceres are billionaire tycoons who own water and air transport corporations.

The police on Ceres (of which another lead character is a detective) are well-intentioned but understaffed, underfunded and moderately corrupt, similar to what we seem to find in large inner-city police departments like the NYPD and LAPD. It felt completely right when they responded to an attempt to kill a police officer with absolutely overwhelming force and little regard for due process and procedure—for this is what real-world police departments almost always do.

But why colonize the asteroid belt at all? Mars is a whole planet, there is plenty there—and in The Expanse they are undergoing terraforming at a very plausible rate (there’s a moving scene where a Martian says to an Earther, “We’re trying to finish building our garden before you finish paving over yours.”). Mars has as much land as Earth, and it has water, abundant metals, and CO2 you could use to make air.Even just the frontier ambition could be enough to bring us to Mars.

But why go to Ceres? The explanation The Expanse offers is a very sensible one: Mining, particularly so-called “rare earth metals”. Gold and platinum might have been profitable to mine at first, but once they became plentiful the market would probably collapse or at least drop off to a level where they aren’t particularly expensive or interesting—because they aren’t useful for very much. But neodymium, scandium, and prometheum are all going to be in extremely high demand in a high-tech future based on nuclear-powered spacecraft, and given that we’re already running out of easily accessible deposits on Earth, by the 2200s there will probably be basically none left. The asteroid belt, however, will have plenty for centuries to come.

As a result Ceres is organized like a mining town, or perhaps an extractive petrostate (metallostate?); but due to lightspeed interplanetary communication—very important in the series—and some modicum of free speech it doesn’t appear to have attained more than a moderate level of corruption. This also seems realistic; the “end-of-history” thesis is often overstated, but the basic idea that some form of democracy and welfare-state capitalism is fast becoming the only viable model of governance does seem to be true, and that is almost certainly the model of governance we would export to other planets. In such a system corruption can only get so bad before it is shown on the mass media and people won’t take it anymore.

The show doesn’t deal much with absolute dollar (or whatever currency) numbers, which is probably wise; but nominal incomes on Ceres are likely extremely high even though the standard of living is quite poor, because the tiny living space and need to import air and water would make prices (literally?) astronomical. Most people on Ceres seem to have grown up there, but the initial attraction could have been something like the California Gold Rush, where rumors of spectacularly high incomes clashed with similarly spectacular expenses incurred upon arrival. “Become a millionaire!” “Oh, by the way, your utility bill this month is $112,000.”

Indeed, even the poor on Ceres don’t seem that poor, which is a very nice turn toward realism that a lot of other science fiction shows seem unprepared to make. In Firefly, the poor are poor—they can barely afford food and clothing, and have no modern conveniences whatsoever. (“Jaynestown”, perhaps my favorite episode, depicts this vividly.) But even the poor in the US today are rarely that poor; our minimalistic and half-hearted welfare state has a number of cracks one can fall through, but as long as you get the benefits you’re supposed to get you should be able to avoid starvation and homelessness. Similarly I find it hard to believe that any society with high enough productivity to routinely build interstellar spacecraft the way we build container ships would not have at least the kind of welfare state that provides for the most basic needs. Chronic dehydration is probably still a problem for Belters, because water would be too expensive to subsidize in this way; but they all seem to have fairly nice clothes, home appliances, and smartphones, and that seems right to me. At one point a character loses his arm, and the “cheap” solution is a cybernetic prosthetic—the “expensive” one would be to grow him a new arm. As today but perhaps even more so, poverty in The Expanse is really about inequality—the enormous power granted to those who have millions of times as much as others. (Another show that does this quite well, though is considerably softer as far as the physics, is Continuum. If I recall correctly, Alec Sadler in 2079 is literally a trillionaire.)

Mars also appears to be a democracy, and actually quite a thriving one. In many ways Mars appears to be surpassing Earth economically and technologically. This suggests that Mars was colonized with our best and brightest, but not necessarily; Australians have done quite well for themselves despite being founded as a penal colony. Mars colonization would also have a way of justifying their frontier idealism that no previous frontiers have granted: No indigenous people to displace, no local ecology to despoil, and no gifts from the surrounding environment. You really are working entirely out of your own hard work and know-how (and technology and funding from Earth of course) to establish a truly new world on the open and unspoiled frontier. You’re not naive or a hypocrite, it’s the real truth. That kind of realistic idealism could make the Martian Dream a success in ways even the American Dream never quite was.

In all it is a very compelling series, and should appeal to people like me who crave geopolitical nuance in fiction. But it also has its moments of huge space battles with exploding star cruisers, so there’s that.

The real Existential Risk we should be concerned about

JDN 2457458

There is a rather large subgroup within the rationalist community (loosely defined because organizing freethinkers is like herding cats) that focuses on existential risks, also called global catastrophic risks. Prominent examples include Nick Bostrom and Eliezer Yudkowsky.

Their stated goal in life is to save humanity from destruction. And when you put it that way, it sounds pretty darn important. How can you disagree with wanting to save humanity from destruction?

Well, there are actually people who do (the Voluntary Human Extinction movement), but they are profoundly silly. It should be obvious to anyone with even a basic moral compass that saving humanity from destruction is a good thing.

It’s not the goal of fighting existential risk that bothers me. It’s the approach. Specifically, they almost all seem to focus on exotic existential risks, vivid and compelling existential risks that are the stuff of great science fiction stories. In particular, they have a rather odd obsession with AI.

Maybe it’s the overlap with Singularitarians, and their inability to understand that exponentials are not arbitrarily fast; if you just keep projecting the growth in computing power as growing forever, surely eventually we’ll have a computer powerful enough to solve all the world’s problems, right? Well, yeah, I guess… if we can actually maintain the progress that long, which we almost certainly can’t, and if the problems turn out to be computationally tractable at all (the fastest possible computer that could fit inside the observable universe could not brute-force solve the game of Go, though a heuristic AI did just beat one of the world’s best players), and/or if we find really good heuristic methods of narrowing down the solution space… but that’s an awful lot of “if”s.

But AI isn’t what we need to worry about in terms of saving humanity from destruction. Nor is it asteroid impacts; NASA has been doing a good job watching for asteroids lately, and estimates the current risk of a serious impact (by which I mean something like a city-destroyer or global climate shock, not even a global killer) at around 1/10,000 per year. Alien invasion is right out; we can’t even find clear evidence of bacteria on Mars, and the skies are so empty of voices it has been called a paradox. Gamma ray bursts could kill us, and we aren’t sure about the probability of that (we think it’s small?), but much like brain aneurysms, there really isn’t a whole lot we can do to prevent them.

There is one thing that we really need to worry about destroying humanity, and one other thing that could potentially get close over a much longer timescale. The long-range threat is ecological collapse; as global climate change gets worse and the oceans become more acidic and the aquifers are drained, we could eventually reach the point where humanity cannot survive on Earth, or at least where our population collapses so severely that civilization as we know it is destroyed. This might not seem like such a threat, since we would see this coming decades or centuries in advance—but we are seeing it coming decades or centuries in advance, and yet we can’t seem to get the world’s policymakers to wake up and do something about it. So that’s clearly the second-most important existential risk.

But the most important existential risk, by far, no question, is nuclear weapons.

Nuclear weapons are the only foreseeable, preventable means by which humanity could be destroyed in the next twenty minutes.

Yes, that is approximately the time it takes an ICBM to hit its target after launch. There are almost 4,000 ICBMs currently deployed, mostly by the US and Russia. Once we include submarine-launched missiles and bombers, the total number of global nuclear weapons is over 15,000. I apologize for terrifying you by saying that these weapons could be deployed in a moment’s notice to wipe out most of human civilization within half an hour, followed by a global ecological collapse and fallout that would endanger the future of the entire human race—but it’s the truth. If you’re not terrified, you’re not paying attention.

I’ve intentionally linked the Union of Concerned Scientists as one of those sources. Now they are people who understand existential risk. They don’t talk about AI and asteroids and aliens (how alliterative). They talk about climate change and nuclear weapons.

We must stop this. We must get rid of these weapons. Next to that, literally nothing else matters.

“What if we’re conquered by tyrants?” It won’t matter. “What if there is a genocide?” It won’t matter. “What if there is a global economic collapse?” None of these things will matter, if the human race wipes itself out with nuclear weapons.

To speak like an economist for a moment, the utility of a global nuclear war must be set at negative infinity. Any detectable reduction in the probability of that event must be considered worth paying any cost to achieve. I don’t care if it costs $20 trillion and results in us being taken over by genocidal fascists—we are talking about the destruction of humanity. We can spend $20 trillion (actually the US as a whole does every 14 months!). We can survive genocidal fascists. We cannot survive nuclear war.

The good news is, we shouldn’t actually have to pay that sort of cost. All we have to do is dismantle our nuclear arsenal, and get other countries—particularly Russia—to dismantle theirs. In the long run, we will increase our wealth as our efforts are no longer wasted maintaining doomsday machines.

The main challenge is actually a matter of game theory. The surprisingly-sophisticated 1990s cartoon show the Animaniacs basically got it right when they sang: “We’d beat our swords into liverwurst / Down by the East Riverside / But no one wants to be the first!”

The thinking, anyway, is that this is basically a Prisoner’s Dilemma. If the US disarms and Russia doesn’t, Russia can destroy the US. Conversely, if Russia disarms and the US doesn’t, the US can destroy Russia. If neither disarms, we’re left where we are. Whether or not the other country disarms, you’re always better off not disarming. So neither country disarms.

But I contend that it is not, in fact, a Prisoner’s Dilemma. It could be a Stag Hunt; if that’s the case, then only multilateral disarmament makes sense, because the best outcome is if we both disarm, but the worst outcome is if we disarm and they don’t. Once we expect them to disarm, we have no temptation to renege on the deal ourselves; but if we think there’s a good chance they won’t, we might not want to either. Stag Hunts have two stable Nash equilibria; one is where both arm, the other where both disarm.

But in fact, I think it may be simply the trivial game.

There aren’t actually that many possible symmetric two-player nonzero-sum games (basically it’s a question of ordering 4 possibilities, and it’s symmetric, so 12 possible games), and one that we never talk about (because it’s sort of boring) is the trivial game: If I do the right thing and you do the right thing, we’re both better off. If you do the wrong thing and I do the right thing, I’m better off. If we both do the wrong thing, we’re both worse off. So, obviously, we both do the right thing, because we’d be idiots not to. Formally, we say that cooperation is a strictly dominant strategy. There’s no dilemma, no paradox; the self-interested strategy is the optimal strategy. (I find it kind of amusing that laissez-faire economics basically amounts to assuming that all real-world games are the trivial game.)

That is, I don’t think the US would actually benefit from nuking Russia, even if we could do so without retaliation. Likewise, I don’t think Russia would actually benefit from nuking the US. One of the things we’ve discovered—the hardest way possible—through human history is that working together is often better for everyone than fighting. Russia could nuke NATO, and thereby destroy all of their largest trading partners, or they could continue trading with us. Even if they are despicable psychopaths who think nothing of committing mass murder (Putin might be, but surely there are people under his command who aren’t?), it’s simply not in Russia’s best interest to nuke the US and Europe. Likewise, it is not in our best interest to nuke them.

Nuclear war is a strange game: The only winning move is not to play.

So I say, let’s stop playing. Yes, let’s unilaterally disarm, the thing that so many policy analysts are terrified of because they’re so convinced we’re in a Prisoner’s Dilemma or a Stag Hunt. “What’s to stop them from destroying us, if we make it impossible for us to destroy them!?” I dunno, maybe basic human decency, or failing that, rationality?

Several other countries have already done this—South Africa unilaterally disarmed, and nobody nuked them. Japan refused to build nuclear weapons in the first place—and I think it says something that they’re the only people to ever have them used against them.

Our conventional military is plenty large enough to defend us against all realistic threats, and could even be repurposed to defend against nuclear threats as well, by a method I call credible targeted conventional response. Instead of building ever-larger nuclear arsenals to threaten devastation in the world’s most terrifying penis-measuring contest, you deploy covert operatives (perhaps Navy SEALS in submarines, or double agents, or these days even stealth drones) around the world, with the standing order that if they have reason to believe a country initiated a nuclear attack, they will stop at nothing to hunt down and kill the specific people responsible for that attack. Not the country they came from; not the city they live in; those specific people. If a leader is enough of a psychopath to be willing to kill 300 million people in another country, he’s probably enough of a psychopath to be willing to lose 150 million people in his own country. He likely has a secret underground bunker that would allow him to survive, at least if humanity as a whole does. So you should be threatening the one thing he does care about—himself. You make sure he knows that if he pushes that button, you’ll find that bunker, drop in from helicopters, and shoot him in the face.

The “targeted conventional response” should be clear by now—you use non-nuclear means to respond, and you target the particular leaders responsible—but let me say a bit more about the “credible” part. The threat of mutually-assured destruction is actually not a credible one. It’s not what we call in game theory a subgame perfect Nash equilibrium. If you know that Russia has launched 1500 ICBMs to destroy every city in America, you actually have no reason at all to retaliate with your own 1500 ICBMs, and the most important reason imaginable not to. Your people are dead either way; you can’t save them. You lose. The only question now is whether you risk taking the rest of humanity down with you. If you have even the most basic human decency, you will not push that button. You will not “retaliate” in useless vengeance that could wipe out human civilization. Thus, your threat is a bluff—it is not credible.

But if your response is targeted and conventional, it suddenly becomes credible. It’s exactly reversed; you now have every reason to retaliate, and no reason not to. Your covert operation teams aren’t being asked to destroy humanity; they’re being tasked with finding and executing the greatest mass murderer in history. They don’t have some horrific moral dilemma to resolve; they have the opportunity to become the world’s greatest heroes. Indeed, they’d very likely have the whole world (or what’s left of it) on their side; even the population of the attacking country would rise up in revolt and the double agents could use the revolt as cover. Now you have no reason to even hesitate; your threat is completely credible. The only question is whether you can actually pull it off, and if we committed the full resources of the United States military to preparing for this possibility, I see no reason to doubt that we could. If a US President can be assassinated by a lone maniac (and yes, that is actually what happened), then the world’s finest covert operations teams can assassinate whatever leader pushed that button.

This is a policy that works both unilaterally and multilaterally. We could even assemble an international coalition—perhaps make the UN “peacekeepers” put their money where their mouth is and train the finest special operatives in the history of the world tasked with actually keeping the peace.

Let’s not wait for someone else to save humanity from destruction. Let’s be the first.

What would an interplanetary economy look like?

JDN 2457397

Today’s post is the second Reader’s Choice topic, chosen by a vote of my Patreons.

Remember, you too can vote on future topics if you pledge at least $10 per month.

Actually, there was a tie between two topics; since I was in an SF mood today, I decided to do this one as the official Reader’s Choice post. The second, “The challenges and possibilities of a global basic income”, I’ll do as a later post. (If I don’t get around to that before the next vote, you can of course always vote for it again.)

Will we ever colonize outer space? Many people thought we’d be there by now.

In Blade Runner, released in 1982, Roy was built and deployed to the outer colonies in 2015, which you may remember as the year that just ended.

Predictions of the future are often wrong, but predictions from the 20th century of the 21st century seem to be consistently overoptimistic about technology. In a past Idiot Free Zone post, I hypothesize that this is due to the confusion between exponential and logistic growth.

Paul Krugman is also a big fan of SF (it is actually about as likely that I’d run into Krugman at Worldcon as at an economics conference), and he wrote a paper on the possibility of interstellar trade way back in 1978. I think he’s kind of satirizing economic theorists actually; he uses sophisticated mathematics to address a problem that doesn’t exist in the real world—just like they do.

I think we will eventually at least reach the point of interplanetary colonization, if not actually interstellar. To begin, let me emphasize that vital distinction. Mars is currently about 60 million kilometers away at its closest approach. The core of the Alpha Centauri system is 4.24 light-years away, which is about 40 trillion kilometers. The distance from Ann Arbor to Toledo is about 84 kilometers. Thus, the difficulty of going to Alpha Centauri is about as much higher than that of going to Mars as the difficulty of going to Mars is compared to going from Ann Arbor to Toledo—each a factor of 700,000 times the distance.

With current technology, we can send robots to Mars (how cool is that? We did get some of the future we were promised). A typical trip takes about half a year. It costs us about $2.5 billion to do that, though India somehow managed to at least make Mars orbit for $75 million. Even if we use the $2.5 billion figure, that still means our current economic output the US and Europe alone could support hundreds of missions per year if we were willing to pay for it. (Devote the entire US military budget to NASA and we could land a new robot on Mars every day.) Interplanetary travel is most definitely feasible.

Interstellar travel on the other hand, is still far out of reach. In principle we are limited by the speed of light; in fact, it’s a good deal worse than that. The fastest we have ever gotten a spacecraft leaving the Solar System is about 60,000 km/h; at that speed it would take almost one billion hours to get to Alpha Centauri, which is over 100,000 years. We will need substantial breakthroughs in spacecraft propulsion before we can even consider sending anything to even the nearest stars. (I wouldn’t give up hope completely, however; in 1901 someone could just as well have criticized H.G. Wells’ The First Men in the Moon on the grounds that no one will ever invent a propulsion system powerful enough to reach the moon.)

By the time we manage interstellar travel, our technology will be so much more advanced it’s hard to even imagine what things will be like. But interplanetary travel we could probably do right now.

So let’s suppose we do in fact establish colonies on other planets—most likely Mars and Mercury, as well as several moons of Jupiter and Saturn. What would our economy look like once we did?

For a decidedly Game of Thrones take on this situation, see The Expanse. Their scientific accuracy is quite good (although they still have sound in space!); so far, their economic accuracy seems pretty good as well, but so far I haven’t seen enough yet to be sure.
One thing I think The Expanse does get right is that asteroid mining is a vital part of the interplanetary trade network. The thing that’s currently keeping us from colonizing other planets is a lack of economic incentives to bear the enormous cost of space travel. Asteroid mining is one thing that might actually provide those incentives, if we can leap just a few more technological hurdles in terms of mining robots and spacecraft propulsion.

Many asteroids contain metals such as silver, gold and platinum at concentrations 20 times as great as anything found on the surface of the Earth. The amount of iron and nickel they contain is even larger; we could supply the entire iron production of the Earth (3.2 billion tonnes) with a single asteroid, 16 Psyche, for the next million years. That one asteroid over 2e19 kg of nearly pure iron-nickel, which is 200 quadrillion tonnes. Many asteroids also contain large concentrations of other useful and rare metals, such as lithium and neodymium.

It is unlikely we would actually try to colonize asteroids (they do in The Expanse, but I’m not sure I buy it). None are large enough to support an atmosphere (kind of by definition), so we’d have to build space stations large enough for permanent habitation. With such ludicrous amounts of iron all around us, that might be possible; but would it be cost-effective? I think it’s more likely that we would have temporary habitats, able to support people for several months or maybe a few years, and people would basically do “tours of duty” working in the asteroids, and then return home. This is similar to how we use space stations right now; you can live there for a long time—the standing record is over a year—but nobody lives their whole life there. It might be a sort of “seasonal” work, where the seasons are decided by large-scale orbital mechanics rather than local planetary axial tilt. (We might have to start doing “seasonal adjustments” to statistics based on this!) Provided that the workers are paid a substantial portion of the spoils—by no means a certainty, as we all know from sweatshops around the world—this work could easily be lucrative enough that you become a millionaire after a tour or two and then retire.

But they might well return home to Mars, since the orbital transfer from the asteroid belt to Mars is considerably easier (it has what we call a lower “delta-v”) than the same transfer all the way back to Earth, and the launch and landing are even easier still. Mars does support an atmosphere—currently very thin and not breathable, but that could change with terraforming. It is also large enough to spread out with room for many homes, greenhouses, power plants, etc., and has enough gravity to at least keep human bodies as a basic level of functioning without too much additional support. (Mars’ gravity is about 40% that of Earth’s.)

Of course, most of the products we make are going to be used on Earth—most of everything is going to be used on Earth, probably for centuries to come. It’s possible that we’ll end up like the British Empire did where the colonies are more populous than the source, but it will take a long time for that to happen. (Moreover, the primary reason—cheap, fertile agricultural land—will not apply unless we happen upon a habitable planet or get very good at terraforming.) This means we will need to ship something from Mars to Earth. But since the delta-v is exceptionally high, we’ll want to ship as little as possible. I think this means that we will do most of the refinement and even manufacturing on Mars, and then ship prefabricated components to Earth. Any process that removes mass will be done on Mars, to minimize the amount of mass that needs to make the trip to Earth.

And what will Earth provide in return? As we import this huge quantity of metal (or metal components), what will we export in return?
Well, one possibility is that we won’t—at first, we (by which I mean “our corporations”) will simply retain ownership of the entire supply chain and do all the accounting as though production were being done entirely on Earth. We won’t think of it as “trade”, just as corporations engaging in a series of prospecting and mining ventures. At least at first.

Yet this will become increasingly unwieldy, just as it became unwieldy for the British Empire to retain control of all its colonies and collect their taxes for the Crown. Communication between Mars, Earth, and the asteroid belt will be relatively fast—a few hours delay at worst—but travel will be very slow and very expensive. Local institutions will form and assert themselves, and may eventually topple the corporate managers, expropriate their assets, and create new governments. The corporations could see the rebellion coming a year in advance from the transmissions, and still be powerless to stop it because the ships will take too long to arrive.

Once new local governments form, we will start thinking of it as “trade”. So what will we be trading? To some extent people on Mars might simply accept Earth currency (perhaps US Dollars, or Euros, or as I like to imagine some unified currency, perhaps the Atlantic Union Dollar); but only if they can then use that Earth currency to buy things they actually need. What will they actually need?

Food, for one. Some amount of food production will be done on Mars by necessity—you can’t survive if you depend entirely on imported food to survive. But it will be expensive, and most likely nutrient-dense but tasteless and monotonous genetically-engineered vegetable products. People will get tired of eating bricks of processed Aresoy(TM) for the 17,000th time and will crave real food; Earth will respond by selling them frozen steaks at $12,000 per kilogram. Probably only luxury foods will be imported, actually; why spend $11,900 for a hamburger when you can spend $12,000 for filet mignon? Nominal income on Mars will be huge—millionaires will be ubiquitous. At purchasing power parity, it may not be so impressive, once you account for the ridiculous cost of food and housing. It’ll be like living in Silicon Valley—on steroids.

Water, perhaps. This one is not as obvious as it may seem. While Earth does have the largest concentration of liquid water (except for a couple of moons of the gas giants), there is plenty of ice in them thar asteroids. It will most likely be cheaper (albeit not cheap) to obtain water by capturing and melting down asteroid ice than to ship it all the way from Earth.

But I think the most important Earth export will beculture. The main products that Martians will want to buy from us will be books, movies, songs, video games, hologram simulations. They will be blueprints, patents, 3D printer schematics. Those who travel to Mars will be bold, adventurous, many of them loners and misfits—but deep down they will still sometimes long for the comforts of the books they read as children, the songs they listened to as teenagers. The beautiful thing about selling culture is that it can be transported almost for free—just add it to the radio transmissions you were already sending. Mars will also produce its own culture, of course, but the much smaller population and constant struggle for survival will mean that most of the cultural flow will be outward from Earth to the colonies rather than the reverse. The Internet won’t work normally between Earth and Mars due to the time delay, but there will be something like it, a local MarsNet that caches material from the Internet on a delay of a few hours and then shares it with the colony. You won’t download webpages in real time, you’ll request them a day in advance. You won’t send instant messages, but sending email will be hardly any different. (Instead of Nigerian princes we’ll start getting scam spam about Martian mining entrepreneurs.) Whoever owns this communication monopoly will become fantastically rich, perhaps even more so than the mining companies themselves—because the mining companies have overhead.

Overall, the increased availability of previously-scarce metals like gold, lithium, and neodymium will make new technologies possible and also widely available, including battery technologies that might finally allow Earth to wean itself off of carbon emissions. (Unfortunately, our current means of spacecraft launch are all very carbon-intensive. We will need to invent nuclear engines that don’t leave fallout so that we can launch with them from the ground.) Like all trade, the mutual imports and exports between Earth and Mars will benefit both societies.

But unless we change course dramatically as a society, interplanetary trade will make one problem even worse, and that is inequality. I am having trouble foreseeing an interplanetary trade system that doesn’t involve making the middlemen who own the shipping and networking companies rich even beyond the wildest dreams of today’s plutocrats. We will witness the birth of humanity’s first trillionaires, individual men (and let’s face it, probably men, unless we figure out gender equality too) who own as much as not just entire countries, but as entire large First World countries. The GDP of France today is $2.8 trillion per year; the CEO of Aresoy or MarsNet could well make more than that on dividends. Of course, that provides him a great incentive to start the project now—but what will it mean for our societies when one person can buy a spaceship as casually as we would buy a cup of coffee?

What really scares me

JDN 2457327

Today is Halloween, so in the spirit of the holiday I thought I’d talk about things that are scary. Not things like zombies and witches and vampires; those things aren’t real (though people do still believe in them in many parts of the world). And maybe that’s part of the point; maybe Halloween is meant to “scare” us like a roller coaster, where we feel some of the epinephrine rush of fear but deep down we know we are safe.

But today I’m going to talk about things that are actually scary, things that are not safe deep down. I could talk about the Republican debate earlier this week, but maybe I shouldn’t get too scary.

In fiction there is whatever sort of ending the author wants to make, usually a happy one. Even tragic endings are written to be meaningful and satisfying. But in real life any sort of ending is possible. I could be driving down the street tomorrow and a semi truck could blindside me and kill me on impact. There’s no satisfying tragedy there, no comeuppance for my hubris or tragic flaw in my character leading to my doom—but this sort of thing kills over 30,000 Americans each year.

But are car accidents really scary? The way they kill just about anyone at random is scary. But there is a clear limit to how much damage they can do. No society has ever been wiped off the face of the Earth because of traffic accidents. There is no way for traffic accidents to risk the survival of the human race itself.

This brings me to the first thing that is really scary: Climate change. Human societies have been wiped off the face of the Earth due to local ecological collapses. The classic example is Easter Island, which did have an ecological collapse, but also suffered greatly from European invaders. Recent evidence suggests that the Vikings fell apart because glaciation broke their trade networks. Jared Diamond argues that a large number of ancient societies have fallen due to ecological collapse.

Yet for the first time we are now facing rapid global climate change, and it is our own doing. (As the vast majority of climate scientists agree.) We are already seeing its effects in flooding, wildfires, droughts, and hurricanes. Positive feedbacks are created, such as heat waves leading to more air conditioning, which draws more electricity that releases more carbon. Even as management of fishing improves, fisheries are still being depleted—because their waters are becoming too warm for the native fish.

Just yesterday the United Nations released a report showing that current promises of reduced carbon emissions will not be sufficient—even if they are followed through, which such promises often aren’t. The goal was to keep warming under 2 C; but it looks like we are looking at more like 2.7 C. That 0.7-degree difference may not seem like much, but in fact it means thousands or even millions of additional deaths. Most of the economic damage will be done to countries near the equator—which is also where the most impoverished people tend to live. The Global Humanitarian Forum estimates that global warming is already killing 300,000 people each year and causing over $100 billion in economic damage.

Meanwhile, there is a campaign of disinformation about climate change, funneled through secretive “dark money” processes (Why are these even allowed!?), including Exxon corporation, which has known for 30 years that they were contributing to climate change but actively suppressed that knowledge in order to avoid regulation. Koch Industries has also funded a great deal of climate change denialism. West Virginia recently tried to alter their science textbooks to remove references to climate change because they considered the scientific facts to be “too political”. Supposedly serious “think tanks” with conservative ideologies twist data in order to support their claims. Rather than be caught lying or denying science, most of the Republican presidential candidates are avoiding talking about the subject altogether.
There is good news, however: More Americans than ever recognize that climate change is real. 7% changed their minds in just the last few months. Even a lot of Republican politicians are finally coming around.

What else is scary? Nuclear war, a Black Swan. This is the most probable way humanity could destroy ourselves; the probability of nuclear war in the next 50 years has been estimated as high as 10%. Every day that goes by with nuclear weapons at the ready is like pulling the trigger in a game of Russian Roulette. We don’t really know how to estimate the probability with any precision; but even 0.1% per year would be a 10% chance over the next century.

There’s good news on this front as well: Slowly but surely, the world is disarming its nuclear weapons. From a peak of 60,000 nuclear weapons in 1986, we are now down to about 10,000. But we shouldn’t get too comfortable, as the estimated number necessary to trigger a global nuclear winter with catastrophic consequences is only about 100. India or Pakistan alone probably has enough to do that. The US or Russia has enough to do it 40 times over. We will need to continue our current disarmament trend for another 30 years before no single nation has enough weapons to trigger a nuclear winter.

Then there’s one more class of scary Black Swans: Mass extinction events. In particular, I’m talking about the Yellowstone Supervolcano, which could erupt at any moment, and the possibility of a large asteroid impact which could destroy cities or even wipe out all life on the surface of the Earth. We are 99.989% sure that TV135 will not do this; but in that 0.02% chance, it would hit with the force of 2500 megatons—50 times larger than any nuclear weapon ever built. Smaller (“smaller”) sub-megaton impacts are actually remarkably common; we average about two per year. If one ever hit a major city, it would be comparable to the Hiroshima nuclear bombing. The Yellowstone supervolcano would not be as catastrophic as a planet-scouring impact, but it would be comparable to a nuclear war and nuclear winter.

With asteroids, there are actually clear things we could do to improve our chances. Above all, we could invest in space exploration and astronomy. With better telescopes and more tracking stations we could see them coming; with better long-range rockets we might be able to deflect them before they get here. A number of different deflection proposals are being studied right now. This is actually the best reason I can think of to keep at least some nuclear weapons on standby; a large nuclear blast positioned at the right place could be effective at destroying an asteroid or deflecting it enough to miss us.

With Yellowstone, there really isn’t much we can do; all we can do at this point is continue to research the supervolcano and try to find ways to reduce the probability of its eruption. It is currently estimated at a just over 1 in 1 million chance of erupting any given year, but that’s a very rough estimate. Fracking near Yellowstone is currently banned, and I think it should stay that way until we have a very clear idea of what would happen. (It’s actually possible it could reduce the probability of eruption, in which case we should start fracking like crazy.)

Forget the zombie apocalypse. I’m scared of the supervolcano apocalypse.