Does the Past Still Exist?

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One of the biggest mysteries of our existence  is also one of the biggest mysteries of physics:  

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time. We experience time as passing, with a  special moment that we call “now”. Now you’re  

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watching this video, half an hour ago you  were doing something else. Whatever you did,  

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there’s no way to change it. And what you will  do in half an hour is up to you. At least that’s  

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how we perceive time. But what physics tells us  about time is very different from our perception.  

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The person who figured this out was  none other than Albert Einstein.  

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I know. That guy again. Turns out he  kind of knew it all. What did Einstein  

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teach us about the past, the present, and the  future? That’s what we’ll talk about today.

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The topic we’re talking about today is  covered in more detail in my new book  

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“existential physics” which will be  published in August. You find more info  

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about the book at existentialphysics dot com We think about time as something that works  

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the same for everyone and every object. If one  second passes for me, one second passes for you,  

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and one second passes for the clouds above.  This makes time a universal parameter. This  

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parameter labels how much time passes  and also what we all mean by “now”.

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Hermann Minkowski was the first to notice that  this may not be quite right. He noticed that  

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Maxwell’s equations of electrodynamics make much  more sense if one treats time as a dimension,  

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not as a parameter. Just like a ball doesn’t  change if you rotate one direction of space  

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into another, Maxwell’s equations don’t change  if you rotate one direction of space into time. 

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So, Minkowski said, we just combine space with  time to a 4 dimensional space-time, and then  

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we can rotate space into time just like we can  rotate two directions of space into each other.  

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And that naturally explains why Maxwell’s  equations have the symmetry they do have.  

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It doesn’t have anything to do  with electric and magnetic fields,  

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it comes from the properties  of space and time themselves.

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I can’t draw a flower, let alone four dimensions,  but I can just about manage two straight lines,  

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one for time and the other for at least one  dimension of space. This is called a space-time  

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diagram. If you just stand still, then your motion  in such a diagram is a straight vertical line.  

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If you move at a constant velocity, your  motion is a straight line tilted at some angle.  

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So if you change velocity, you rotate in  space-time. The maximal velocity at which  

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you can move is the speed of light, which by  convention is usually drawn at a 45-degree angle.

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In space we can go forward-backward, left right,  or up down. In time we can only go forward,  

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we can’t make a u-turn, and there aren’t any  driveways for awkward three-point turns either.  

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So time is still different from space in some  respect. But now that time is also a dimension,  

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it’s clear that it’s just a label for coordinates,  there’s nothing universal about it. There are many  

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ways to put labels on a two-dimensional space  because you can choose your axes as you want.  

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The same is the case now in space-time. Once you  have made time into a dimension, the labels on it  

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don’t mean much. So what then is the time that we  talk about? What does it even mean that time is a  

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dimension? Do other dimensions exist? Supernatural  ones? That could explain the strange sounds you’ve  

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been hearing at night? No. That's a separate  problem I'm afraid I can't help you with.

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It was Albert Einstein who understood what  this means. If we also want to understand it,  

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we need four assumptions. The speed of light  in vacuum is finite, it’s always the same,  

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nothing can go faster than the speed of light,  and all observers’ viewpoints are equally valid.  

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This formed the basis of Einstein’s  theory of Special Relativity.  

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Oh, and also, the observers don’t have to  exist. I mean, this is theoretical physics,  

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so we’re talking about theoretical observers,  basically. So, if there could be an observer  

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with a certain viewpoint then then that  viewpoint is equally valid as yours.

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Who or what is an observer? Is an ant an observer?  A tree? How about a dolphin? What do you need to  

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observe to deserve being called an observer and  what do you have to observe with? Believe it or  

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not, there’s actually quite some discussion about  this in the scientific literature. We’ll side-step  

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this, erm, interesting discussion and use the  word “observer” the same way that Einstein did,  

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which is a coordinate system. You see, it’s a  coordinate system that a theoretical observer  

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might use, dolphin or otherwise. Yeah, maybe  not exactly what the FBI thinks an observer is,  

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but then if it was good enough for Einstein, it’ll  be good enough for us. So Einstein’s assumption  

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basically means any coordinate system should be as  good as any other for describing physical reality.

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These four assumptions sound rather innocent at  first but they have profound consequences. Let’s  

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start with the first and third: The speed of light  is finite and nothing goes faster than light. You  

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are probably watching this video on a screen,  a phone or laptop. Is the screen there now?  

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Unless you are from the future watching this video  as a hologram in your space house, I'm going to  

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assume the answer is yes. But a physicist might  point out that actually you don’t know. Because  

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the light that’s emitted from the screen now  hasn’t reached you yet. Also if you are from  

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the future watching this as a hologram, make sure  to look at me from the right. It’s my good side.

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Maybe you hold the phone in your hand, but nerve  signals are ridiculously slow compared to light.  

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If you couldn’t see your hand  and someone snatched your phone,  

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it’d take several microseconds for  the information that the phone is gone  

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to even arrive in your brain. So how  do you know your phone is there now?

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One way to answer this question  is to say, well, you don’t know,  

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and really you don’t know that anything  exists now, other than your own thoughts.  

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I think, therefore I am,  as Descartes summed it up.  

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This isn’t wrong – I’ll come back to this later –  but it’s not how normal people use the word “now”.  

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We talk about things that happen “now” all the  time, and we never worry about how long it takes  

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for light to travel. Why can’t we just agree on  some “now” and get on with it? I mean, think back  

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to that space-time diagram. Clearly this flat line  is “now”, so let’s just agree on this and move on.

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Okay, but if this is to be physics rather  than just a diagram you have to come up with  

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an operational procedure to determine what we  mean by “now”. You have to find a way to measure  

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it. Einstein did just that in what he called  Gedankenexperiment, a “thought experiment”.

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He said, suppose you place a mirror to your  right and one to your left. You and the mirrors  

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are at fixed distance to each other, so in  the space time diagram it looks like this.  

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You send one photon left and one right, and make  sure that both photons leave you at the same time.  

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Then you wait to see whether the photons  come back at the same time. If they don’t,  

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you adjust your position until they do. Now remember Einstein’s second assumption,  

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the speed of light is always the same. This means  if you can send photons to both mirrors and they  

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come back at the same time, then you must be  exactly in the middle between the mirrors.  

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The final step is then to say that at exactly  half the time it takes for the photons to return,  

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you know they must be bouncing off the mirror. You  could say “now” at the right moment even though  

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the light from there hasn’t reached you yet. It  looks like you’ve found a way to construct “now”.

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But here’s the problem. Suppose you have a friend  who flies by at some constant velocity, maybe in a  

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space-ship. Her name is Alice, she is much cooler  than you, and you have no idea why she's agreed to  

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be friends with you. But here she is, speeding  by in her space-ship left to right. As we saw  

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earlier, in your space-time diagram, Alice moves  on a tilted straight line. She does the exact  

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same thing as you, places mirrors to both sides,  sends photons and waits for them to come back,  

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and then says when half the time has passed  that’s the moment the photons hit the mirrors.

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Except that this clearly isn’t  right from your point of view.  

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Because the mirrors to her right are in the  direction of her flight, so the light takes longer  

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to get there than it does to the mirrors on the  left, which move towards the light. You would say  

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that the photon which goes left clearly hits the  mirror first because the mirror’s coming at it.  

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From your perspective, she just doesn’t notice  because when the photons go back to Alice,  

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the exact opposite happens. The photon coming from  left takes longer to get back, so the net effect  

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cancels out. What Alice says happens “now”  is clearly not what you think happens “now”.

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For Alice on the other hand, you are the one  moving relative to her. And she thinks that  

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her notion of “now” is right and yours is wrong.  

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So who is right? Probably Alice, you  might say. Because she’s much cooler  

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than you. She owns a spaceship, after  all. Maybe. But let’s ask Einstein.

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Here is where Einstein’s forth assumption comes  in. The viewpoints of all observers are equally  

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valid. So you’re both right. Or, to put it  differently, the notion of “now” depends on the  

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observer, it is “observer-dependent” as physicists  say. Your “now” is not the same as my “now”.  

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If you like technical terms, this is also  called the relativity of simultaneity.

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These mismatches in what different observers think  happens “now” are extremely tiny in every-day  

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life. They only become noticeable when relative  velocities are close by the speed of light,  

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so we don’t normally notice them. If you and I  talk about who knocked at the door right now,  

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we won’t misunderstand each other. If we’d zipped  around with nearly the speed of light, however,  

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referring to “now” would get very confusing.

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This is pretty mind-bending already, but wait, it  gets wilder. Let us have a look at the space-time  

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diagrams again. Now let us take *any* two events  that are not causally connected. This just means  

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that if you wanted to send a signal from one to  the other, the signal would have to go faster  

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than light, so signaling from one to the other  isn’t possible. Diagrammatically this means  

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if you connect the two events the line has an  angle less than 45 degrees to the horizontal.

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The previous construction with the mirrors shows  that for any two such events there is always some  

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observer for whom those two events happen  at the same time. You just have to imagine  

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the mirrors fly through the events and the  observer flies through directly in the middle.  

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And then you adjust the velocity until the  photons hit both events at the same time.

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Okay, so any two causally disconnected events  happen simultaneously for some observer. Now  

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take any two events that are causally connected.  Like eating too much cheese for dinner and then  

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feeling terrible the morning after. Find some  event that isn’t causally connected to either.  

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Let’s say this event is a supernova  going off in a distant galaxy.  

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There are then always observers for whom the  supernova and your cheese dinner are simultaneous,  

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and there are observers for whom the supernova  and your morning after are simultaneous.

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Let’s then put all those together. If you  are comfortable with saying that something,  

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anything, exists “now” which isn’t here, then,  according to Einstein’s fourth assumption,  

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this must be the case for all observers. But if  all the events that you think happen “now” exist  

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and all other observers say the events that  happen at the same time as those events,  

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then all events exist “now”. Another way to  put it is that all times exist in the same way.

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This is called the “block universe”. It’s  just there. It doesn’t come into being,  

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it doesn’t change. It just sits there.

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If you find that somewhat hard to accept, there  is another possibility to consistently combine  

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a notion of existence with Einstein’s  Special Relativity. All that I just said  

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came from assuming that you are willing to say  something exists now even though you can’t see  

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or experience it in any way. If you are willing  to say that only things exist which are now  

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and here, then you don’t get a block universe.  But maybe that’s even more difficult to accept. 

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Another option is to simply invent a notion of  “existence” and define it to be a particular  

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slice in space-time for each moment in time.  This is called a “slicing” but unfortunately  

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it has nothing to do with pizza. If it  had any observable consequences, that  

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would contradict the fourth assumption Einstein  made. So it’s in conflict with Special Relativity  

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and since this theory is experimentally extremely  well confirmed, this would almost certainly mean  

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the idea is in conflict with observation.  But if you just want to define a “now” that  

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doesn’t have observable consequences, you can do  that. Though I’m not sure why you would want to.

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Quantum mechanics doesn’t change anything about  the block universe because it’s still compatible  

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with Special Relativity. The measurement update  of the wave-function, which I talked about in  

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this earlier video, happens faster than the speed  of light. If it could be observed, you could use  

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it to define a notion of simultaneity. But it  can’t be observed, so there’s no contradiction.

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Some people have argued that since  quantum mechanics is indeterministic,  

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the future can’t already exist in the block  universe, and that therefore there must also  

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be a special moment of “now” that divides  the past from the future. And maybe that  

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is so. But even if that was the case, the  previous argument still applies to the past.  

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So, yeah, it’s true. For all we currently know,  the past exists the same way as the present.

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So you thought this is a video  about Special Relativity,  

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but then I’ve been talking  about quantum mechanics again.  

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Indeed, I now have an entire course  about quantum mechanics up at Brilliant  

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which accompanies my videos on the topic.

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Brilliant is an amazing tool for learning with  courses on a large variety of topics in science  

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and mathematics. Our new course will give you an  introduction to superpositions and entanglement,  

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the uncertainty principle, non-commutativity,  and Bell’s theorem. And you can then build up  

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your knowledge with Brilliant’s courses on quantum  objects and quantum computing or linear algebra,  

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or wherever you want to go after this. Like all  their courses, our new course is interactive and  

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will challenge you with questions so you  can check your understanding right away.

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I had a lot of fun working  with Brilliant’s team on this,  

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and I hope you’ll enjoy it too. To support  this channel and learn more about Brilliant,  

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go to Brilliant dot org slash  Sabine and sign up for free.  

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The first 200 subscribers using this link will get  20 percent off the annual premium subscription.

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Thanks for watching, see you next week.