Event Horizons May Not Be What We Thought They Were

Thank you to Babel for supporting PBS. Don't panic, but it's possible that an event horizon is forming right behind you right now. Don't bother looking. You won't see it. It definitely won't look like the classic picture of the black hole that you're probably familiar with. You won't even know that it's growing to envelop you until it's way too late. Before we get started, a couple of quick announcements. First, we have some new data. Liking and commenting really does help get the episodes shared. So, you know, please do both

of those things. And we've also learned that the number one reason that people support us on Patreon isn't actually the perks. It's simply to support the Spacetime community and the work that we do. So, for those of you who do support, thank you so much. But don't get me wrong, there are perks and they're good. There's a link in the description if you'd like to join. This really would be a huge help. Next up, we're excited to announce our new Rocket Equation coffee mug so you can know exactly how much caffeine you need to achieve escape velocity. We also still have our

Fates of the Universe UV Glow T-shirt and hoodie, which lights up after sun exposure. So whether you're rooting for the big rip, the big crunch, or the big freeze, you can wear your prediction for the universe's ultimate fate. Now onto the episode. By now, we all have an idea of what black holes are supposed to look like. Discs of absolute darkness on the sky, surrounded by gravity warped starfields, and the final electromagnetic screams of stuff about to fall in. We think of the black hole as this roughly spherical surface of lightlessness. And the name we give that surface

is the event horizon. If I were to ask where is the black hole, you might point to the event horizon. And that would be fair because a black hole is really defined as something with an event horizon. The surface of no escape surrounding a region so packed with mass and energy that even light becomes trapped. The event horizon is as good a wear as anything for the black hole. And if I were to ask what is the black hole, it seems fair to answer anything inside that horizon. Well, it turns out these answers are somewhere between inadequate and just plain wrong. Even the

question, when does the horizon exist isn't that simple. Event horizons are actually much harder to pin down both in space and time. And when it comes to black holes, a little bit of ambiguity can get you into a lot of trouble. So for safety sake, let's get clear about the event horizon. If we define the event horizon as that surface from which light cannot escape, we need to ask escape to where? One pretty reasonable answer would be to require that in order to be considered above the event horizon, light has to be able to truly escape, which means it must be able to get far

enough away from the black hole that it no longer is affected by its gravity. This is actually close to the formal definition. Light must be able to reach infinite distance which is physics ees for very far away. But this definition is already at odds with how we tend to imagine the event horizon as the scary black disc or sphere. Let's approach that disc then to investigate. We'll travel to the very near vicinity of what we think of as an event horizon. Now, after collecting some Hawking radiation or whatever, we switch on our ridiculously powerful rockets to move away.

Because we carefully stayed above what looks to us like the horizon, we're able to make some headway. But then, misfortune strikes. A giant asteroid or something falls into the black hole from above us and the black hole grows in mass and the event horizon expands and we're enveloped. But according to our earlier definition, if we or if light cannot escape to an extreme distance, then we were already beneath the event horizon and we're already doomed. Yes, something that black surface did expand to envelop us, but it wasn't the true event horizon at all. So, let's dig a little

deeper into the formal definition of the event horizon because it completely changes the what, where, and even the when of our understanding of a black hole. The textbook definition, the one that Steven Hawking and George Ellis sit down in their book, The Large Scale Structure of Spacetime, is as follows. An event horizon is the boundary of the causal past of future null infinity. The causal past of future null infinity. Okay, super helpful. Well, we can break it down maybe a little further. We'll use a Penrose diagram. Longtime viewers will remember these and it'll make

things a little clearer, hopefully. Before we complicate things by adding black holes, here's a Penrose diagram of an infinite flat universe. Time increases upwards and one dimension of space is traced horizontally, but the contours of space and time are curved so that the path of light is always 45°. And those lines are also increasingly squished together towards the edges so that infinite space fits in this finite map. The points at the top and bottom represent our infinite future and past. And the left and right points are infinite spatial boundaries. But it's the diagonal

edges of the diagram that we need to pay attention to. These are the null infinities that Hawking and Ellis are talking about. In particular, the future null infinity is where light rays end in the infinite future. And the past null infinity is where they appear to come from if we trace them back in time forever. Now we can add a black hole to the Penrose diagram like this. This is an eternal black hole. It was always there and always will be there. It's just sitting out there to our left and any motion in that direction will eventually reach it. And that means we can replace

one future null infinity by the event horizon. Below the event horizon, space and time grid lines actually switch place. Moving up on this diagram is equivalent to falling deeper in the black hole towards the inevitable destination of the black hole center. the singularity which occupies all future times inside the black hole. We have previous episodes that explain all of this in more detail. With this sort of diagram, we can see that nothing can escape the black hole. In order to escape, something would need to take a path shallower than 45° and that means going faster

than light. Even light gets stuck forever at the event horizon if it starts there and inevitably at the singularity even if it was trying to move outwards. Hawking and Ellis's definition is clearer in the context of this diagram. They define an event horizon as the boundary of the causal past of future null infinity. This is the future null infinity and its causal past is anything that can get to it traveling no greater than light speed. That means the entire universe except the region below the event horizon. Nothing behind that boundary can affect future infinity or

indeed anything else in the universe that isn't itself behind the same event horizon. Okay, so it feels like we're saying the same thing that we already knew but with more words and more lines. But crucially, we've now been precise enough about black holes as a causal structure. There's something that determines what events are allowed and forbidden in the universe. In doing this, we remove a lot of ambiguity that we ran into earlier. But we also discover something really strange. The event horizon definition is no longer local. It doesn't refer to a single location in

space or point in time. It's the boundary below which neither you nor light rays can escape to a great distance, aka reach future null infinity, even if the black hole that eventually traps you hasn't started forming yet. So the event horizon is a property of the entire spaceime reaching all the way into infinite future. It's not just a statement about what is possible now, but what will be possible based on everything that will happen to this patch of spaceime. Physicists sometimes describe the event horizon as being teological from the ancient Greek term telos

meaning final purpose. It tells us about the final state of the universe, the paths that make it out to infinity and those that eventually end up stuck inside the black hole. That's what I mean when I say that an event horizon might have just passed you right now and you wouldn't even realize. Let's do another thought experiment to see why. We'll start back on Earth. Relatively flat space free of black holes. However, for unfortunate reasons that we don't need to get into, but may involve vogons, there's a spherical shell of radiation of light collapsing towards us. This is an example of the

Va spacetime devised by Indian physicist Prahalad Vaja as a toy model to explore spaceimes and event horizons of a collapsing star without all of the messy matter. In this thought experiment, it feels like there's no event horizon as the shell of radiation converges on us. We don't even know that it's coming because no signal can travel faster than the radiation zone collapse. It's ultimately going to form a black hole with a radius governed by the amount of energy in that radiation. But according to our formal definition, the event horizon forms long before the black

hole. In fact, it grows from the center of the collapsing sphere at the speed of light, reaching its maximum size when it intercepts the infalling radiation. That's when the black hole truly forms, but the horizon was already there. To visualize this, let's say that you're at the center of the collapsing shell and there's a lastditch effort to escape. You shoot a lighteed signal out into space to see if any passing spaceships will beam you up. If your signal makes it beyond the ultimate size of the event horizon before the incoming radiation crosses that same point,

then it escapes and maybe you hit your way out of there. But if not, then it and you remain stuck behind the horizon. If you send your signal too late, then it never reaches future null infinity. So by our definition, it was always behind the true event horizon, trailing it as it expands to become a black hole. Let's see what the Penrose diagram looks like for a Vega spacetime. It starts like our black hole-free diagram, which we'll cut in half because who cares about this entire side of the universe? The sphere of collapsing radiation looks like this single line in our one

dimension of space. It eventually reaches us, but the black hole it forms comes fully into existence when it collapses below that certain radius. The event horizon is then a diagonal line upwards from that point. Just as in our black hole containing Penrose diagram, the spaceime within that event horizon is terminated by a singularity. Now, it's easy to see which light rays escape the forming event horizon and which don't. Ones that we send out early enough to reach future null infinity are the ones that escape. Those that depart too late fail to pass the involing radiation before

the black hole forms. But these rays were doomed from the very start. And so we need to trace the true event horizon backwards to encompass this entire region. We have a part of the universe that is trapped even though it doesn't know that it's in a black hole. So yeah, a nasonent event horizon might be forming behind your couch as we speak. You might want to check that out. Although you'll have to wait until the end of the universe before you can be absolutely certain. A secret event horizon could be due to the collapse of something huge, a giant region of the galaxy

or even the universe billions of years from now. All of this is a weird way to think about event horizons, but does anything really change? Who cares if we can't find the horizon? Well, the most obvious problem is that an event horizon is used to define the boundary of a black hole. So, it makes it hard to talk about where a black hole is. It contradicts our astrophysical intuition. We know that there is a black hole at the center of our galaxy called Sagittarius A star and that stars will get eaten if they get within a certain distance. But this local description feels at odds

with the teological definition. This is even more apparent when we try to simulate the merges of black holes on a computer. Because Einstein's equations are difficult to work with in these highly dynamical regimes, we rely on simulations to tell us what the spaceime will look like, we set up Einstein's equations to describe two black holes in spiraling, then evolve the simulation forward in time until the black holes merge, and we're left with a single black hole. But where and with what shape are the event horizons of the merging black holes and of the final result? If

a horizon is teological, then it's defined across the entirety of the simulation to future infinity. We could get a single time slice out to see how spacetime has evolved, but it won't tell us where the horizon is. We could possibly trace light rays back in time from the end of the simulation and look for the boundary of a region from which no light gets out alive. And that's very much in the spirit of Hawking and Ellis's definition. But this is very awkward as a way to find black holes and not necessarily very instructive if we care about the local shape of spaceime during the simulation.

And besides, we still want to know what to call that black surface that we think we're escaping but are really doomed because the real event horizon is already above us. In the special case of a black hole that's done forming and will never absorb new stuff, that black surface really is the event horizon in the technical sense that we just defined. But in the real universe where black holes tend to keep growing, we need another name for the current snapshot of the black holes boundary. And that name is the apparent horizon where the formal event horizon represents the

global inescapable boundary integrated across all future time. The apparent horizon is a more local beast. It's the locally inescapable boundary, the thing that you can't exit even right now, regardless of whether you can make an ultimate escape. The formal definition of the apparent horizon is also in terms of what light rays can do. But now it's not whether they can reach future null infinity. It's whether they can make any progress whatsoever in the outward direction. Technically, we say that the apparent horizon is the outermost surface from which all outward-

facing null geodysics are converging inwards. Having a local definition of the horizon is nice, especially because it lets us understand what things look like if we're not at null infinity or otherwise really far away. When we see these awesome simulations of merging black holes, what we're seeing is the evolution of the apparent horizon. So why bother with the first definition of the event horizon at all? Well, it's because the apparent horizon is relative. Every observer will agree on the definition of the true event horizon, the ultimately inescapable region. But

the definition of the apparent horizon varies not just over time, but also with frame of reference. In relativity, your sense of now varies with your velocity and the curvature of spaceime. Each sense of the present is a 3D spatial slice out of the four-dimensional spaceime. And that slicing changes with perspective. The apparent horizon will also change between these slicings. And it's even possible to find slicings or definitions of a specially extended now that include a black hole, but in which the apparent horizon disappears. But that's not true of the true event horizon.

If you're behind that, it doesn't matter how you slice spacetime, you are stuck. In fact, every possible apparent horizon is guaranteed to always lie inside or on the actual event horizon. In this sense, the apparent horizon gives a conservative estimate about the extent of the black hole. It also gives a much more useful way to study the behavior of dynamical black holes. black holes that are currently feeding like in quazars or in merging black holes. In that case, the apparent horizon does something quite unexpected. You have these apparent horizons for

the inspiraling black holes that warp as they get close, but the apparent horizon of the final isn't just a smooth merging of the two. That larger joint apparent horizon forms only in the instant that the event horizons merge. So, the apparent horizon is far from a substitute for the event horizon. It's a genuinely different object with its own interesting properties. So, what, where, and when is an event horizon? And is there one forming behind you right now? Well, if you care about what's happening close to a black hole at a particular time, then you need to get creative.

You need to choose reference frames and ask where for that observer light appears to turn inwards at the apparent horizon. But if you want the most clear definition, the definition that matters if you want to escape a black hole, then the true event horizon is not a property of local space or immediate time. It's a thing defined by the past and the future and exists as a causal boundary cutting its way through spaceime. Thank you to Bubble for supporting PBS. If you spend any time online, you might have found that today's world is highly international. That's why Babel teaches

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