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00:13
I started this series saying that relativity is about understanding how things look from different perspectives, and in particular, understanding what does and doesn't look different from different perspectives. And at this point you'd be justified to feel like we've kind of just trashed a bunch of the foundational concepts of physical reality: we've shown how our perceptions of lengths and spatial distances, time intervals, the notion of simultaneous events, and so on, are not absolute: they're different when viewed from different moving perspectives, and so
00:39
aren't universal truths. And if we can't agree on the length of something, what can we agree on? Anyway, the point is, this relativity thing so far kind of just feels like it's leaving us hanging. I mean, all we've really got is the fact that the speed of light in a vacuum is constant from all perspectives – which, while it's true, doesn't feel nearly as helpful in describing objects and events the way that lengths and times are.
01:01
Luckily, there is a version of length and time intervals that's the same from all moving perspectives, the way the speed of light is. You know how if you have a stick that's 10 meters long and you rotate it slightly and measure its length, it won't be 10 meters long in the x direction any more - it'll be shorter? Now, if you know some math you'll tell me it's not actually shorter, and you can still calculate its true length using the pythagorean theorem as the square root of its horizontal
01:24
length squared plus its vertical length squared. And yes, this is the case. You can use the pythagorean theorem to calculate the true length of the stick regardless of how it's rotated. But you don't need to use the pythagorean theorem at all - if you just rotate the stick back so that it's a hundred percent lying in the x direction, then you just measure it as 10 meters long and that's that.
01:44
No pythagorean theorem necessary. In some sense, this is what gives us justification to use the pythagorean theorem to calculate the length of rotated things – sure, it's important that the pythagorean theorem always gives the same answer regardless of the rotation, but it's critical that it agrees with the actual length we measure when the object isn't rotated.
02:03
And it turns out there's a version of the pythagorean theorem for lengths and times in spacetime that allows us to measure the true lengths and durations of things - the lengths and durations they have when they're not rotated. Except, as you know from Lorentz transformations, rotations of spacetime correspond to changes between moving perspectives, so true length and true duration in spacetime correspond to the length and duration measured when the object in question isn't moving - that is,
02:28
true length and true time are those measured from the perspective of the object in question. For example, suppose I'm not moving and I have a lightbulb with me which I turn off after four seconds. As we know, any perspective moving relative to me will say I left my lightbulb on for more than four seconds – like, you, moving a third the speed of light to my left, will say I left it on for 4.24 seconds – that's time dilation.
02:50
However, this is where the spacetime pythagorean theorem comes in – it's like the regular pythagorean theorem, but where instead of taking the square root of the sum of the squares of the space and time intervals, you take the square root of their difference (\sqrt{\Delta t^{2}-\Delta x^{2}}). Now we need a quick aside here to talk about how to add and subtract space and time intervals from each other – I mean, one is in meters and the other seconds, so at first it seems impossible to compare them to each other.
03:13
But in our daily lives we directly compare distances and times all the time – we say that the grocery store is five minutes away, even though what we actually mean is that it's 1 km away; it just takes us 5 minutes to bike 1 km, so we use that speed to convert distance to time. In special relativity, however, we convert not with bike speed but with light speed - that is, how long it would take light to go a given distance.
03:35
For example, light goes roughly 300 million meters in one second, so a light-second is a way to compare one second of time with one meter (and second is WAAAAAAY bigger!). So, back in our example situation, where from my not-moving perspective I had my lightbulb on for 4 seconds - from your perspective it was on for 4.
03:53
24 seconds before I turned it off, in which time I had traveled 1.4 light-seconds to your right. And the spacetime version of the pythagorean theorem simply tells you to square the time, subtract the square of the distance (measured using light-seconds), and take the square root of the whole thing. Voilá - 4 seconds! We used observations from your perspective to successfully calculate the true duration I had my light on - the duration that I, not moving, experienced.
04:20
And it works for any moving reference frame. Here, from a perspective in which I'm moving 60\% the speed of light to the right, I left my lightbulb on for 5 seconds, during which time I moved 3 light seconds to the right. Square the time, subtract the distance squared, take the square root, and again, we've got 4 seconds: the true, proper duration of time for which my lightbulb was on.
04:42
This all works similarly for true, proper lengths, too: here are two boxes that spontaneously combust 1200 million meters apart – at least, it's 1200 million meters from my perspective, in which the boxes aren't moving. From your perspective, in which the boxes and I are moving a third the speed of light to the right, the distance between the combusting boxes is now 1273 million meters, and the time between when they spontaneously combust is now 1.
05:07
41 seconds, which converts, using the speed of light, to 425 million meters. We're again ready for the spacetime pythagorean theorem: square the distance, subtract the square of the time (measured in light-meters), and take the square root of the whole thing to get... you guessed it, 1200 million meters. Specifically, what we just did was use Lorentz-transformed observations from your perspective to calculate the true distance between the boxes from their (and my) perspective.
05:31
And it would work from any other moving perspective, too. The bottom line is that in special relativity, while distances and time intervals are different from different perspectives, there is still an absolute sense of the true length and true duration of things that's the same from everyone's perspective: anyone can take the distances and times as measured from their perspective and use the spacetime pythagorean theorem to calculate the distance and time experienced by the thing whose distance or time you're
05:58
talking about. Perhaps it should be called “egalitarian distance” and “egalitarian time”. But sadly no, these true distances and times are typically called “proper length” and “proper time”. And the spacetime pythagorean theorem, because it combines intervals in space and time together, has the incredibly creative name “spacetime interval”.
06:12
But don't let that get you down: spacetime intervals allow us to be self-centered and lazy! Spacetime intervals allow fast-moving people to understand what life is like from our own, non-moving perspectives. The astute among you may have noticed that there was some funny business going on regarding whether or not we subtracted distance from time or time from distance - the short story is that it just depends on whether you're dealing with a proper length or a proper time.
06:39
The long story is an age-old debate about what's called “the signature of the metric”. And if you want practice using proper time and spacetime intervals to understand real-world problems, I highly recommend Brilliant.org's course on special relativity. There, you can apply the ideas from this video to scenarios in the natural world where special relativity really affects outcomes, like the apparently paradoxical survival of cosmic ray muons streaming through Earth's atmosphere.
07:04
The special relativity questions on Brilliant.org are specifically designed to help you go deeper on the topics I'm including in this series, and you can get 20% off of a Brilliant subscription by going to Brilliant.org/minutephysics. Again, that's Brilliant.
07:19
org/minutephysics which gets you 20% off premium access to all of Brilliant's courses and puzzles, and lets Brilliant know you came from here.
在探讨相对论的世界中,我们试图理解不同视角下的事物样貌,尤其是那些在不同视角下看起来相同或不同的概念。你是否曾感到,我们在颠覆物理现实的基础概念?长度、空间距离、时间间隔,甚至事件的同时性,都不是绝对的。它们随着观察者的移动视角而变化,并非宇宙的普遍真理。
那么,在长度都无法达成共识的情况下,我们还能在哪些方面达成一致?这正是相对论让我们感到困惑的地方。但幸运的是,存在一种长度和时间间隔的度量,它们在所有移动视角中都是相同的,就像光速在真空中恒定不变一样。
让我们以一根棍子为例。如果你有一根10米长的棍子,稍微旋转它并测量其长度,它将不再是10米。但你知道吗?这并不是因为它真的变短了。你可以使用勾股定理计算出它的真实长度,即水平长度的平方加上垂直长度的平方的平方根。然而,你并不需要使用勾股定理——如果你只是将棍子旋转回完全位于x方向,那么你只需测量它作为10米长,就这么简单。
在时空中的长度和时间也有类似的情况。存在一种勾股定理的版本,允许我们测量事物的真实长度和持续时间——即当它们没有“旋转”时的长度和持续时间。在洛伦兹变换中,时空的“旋转”对应于移动视角之间的变化,因此真实的长度和时间是从物体自身的视角测量的。
假设我静止不动,手里有一个灯泡,我在4秒后将其关闭。从任何相对于我移动的视角来看,他们会认为我让灯泡亮了超过4秒。但这就是时空勾股定理发挥作用的地方——它类似于常规的勾股定理,但你需要从时间和空间间隔的平方差中取平方根(√(Δt²-Δx²))。
在我们的日常生活中,我们经常直接比较距离和时间——我们说杂货店离我们5分钟路程,即使实际上它离我们1公里远。在特殊相对论中,我们不是用自行车速度来转换距离和时间,而是用光速——即光到达给定距离所需的时间。
回到灯泡的例子,从你的视角,灯泡亮了4.24秒,在这段时间里,我向右移动了1.4光秒。使用时空勾股定理,我们只需对时间进行平方,减去距离的平方,然后取平方根。就这样,我们成功地计算出我静止时灯泡亮的真实时间——4秒。
在特殊相对论中,虽然距离和时间间隔在不同的视角下是不同的,但仍然存在一个关于事物的真实长度和持续时间的绝对概念。任何人都可以从自己的视角测量距离和时间,并使用时空勾股定理来计算物体经历的距离和时间。
这种时空间隔的概念让我们能够以自我为中心,懒惰地理解从我们自己的、非移动视角看世界的方式。虽然关于距离和时间的减法顺序存在一些争论,但这并不影响我们使用时空间隔来解决实际问题。
如果你想要更深入地了解特殊相对论,我强烈推荐Brilliant.org上的相关课程。在那里,你可以将视频中的概念应用到真实世界中,特殊相对论真正影响结果的各种场景中。