Sean Carroll #3

Sean Carroll · 27,402 词 · 查看原文 ↗
物理与宇宙学音乐与艺术太空与探索生物与进化AI 与机器学习
📋 章节目录
0:00 Introduction · 介绍
1:54 General relativity · 广义相对论
14:13 Black holes · 黑洞
19:03 Hawking radiation · 霍金辐射
23:10 Aliens · 外星人
32:06 Holographic principle · 全息原理
56:29 Dark energy · 暗能量
1:02:29 Dark matter · 暗物质
1:11:25 Quantum mechanics · 量子力学
1:32:47 Simulation · 模拟
1:35:09 AGI · 通用人工智能
1:49:33 Complexity · 复杂
2:02:17 Consciousness · 意识
2:11:23 Naturalism · 自然主义
2:15:40 Limits of science · 科学的局限性
2:20:25 Mindscape podcast · 思维景观播客
2:30:21 Einstein · 爱因斯坦
🔑 关键词
seancarrolldonblackuniversespacequantumholedarkrelativityenergytheorygoingmattermechanicsgeneralentropyholescomplexityhuman
💬 精彩语录
"No, I think that was completely an illusion. I think it was a very, very reasonable illusion to be under. There are illusions, there are substantive claims about the world that go beyond predictions that we can make and verify which later turned out to be wrong and the existence of God was one of them. If those people at that time had abandoned their belief in God and replaced it with a mechanistic universe, they would’ve done just as well at understanding things. Again, because there are so many things they didn’t understand, it was very reasonable for them to have that belief, it wasn’t that they were dummies or anything like that. But that is, as we understand the universe better and better, some things stick with us, some things get replaced."
不,我认为那完全是幻觉。我认为这是一种非常非常合理的幻想。有一些幻觉,有一些关于世界的实质性主张超出了我们可以做出和验证的预测,但后来证明这些预测是错误的,上帝的存在就是其中之一。如果当时的人们放弃对上帝的信仰,代之以机械论的宇宙,他们对事物的理解也会同样好。再说一次,因为他们不明白的事情太多了,所以他们有这样的信念是非常合理的,而不是说他们是傻瓜之类的。但随着我们对宇宙的了解越来越深入,有些东西会一直伴随着我们,有些东西会被取代。
— Sean Carroll (02:10:40)
"Yeah, get behind a computer. My way of doing it … So, my wife, Jennifer, is a science writer but it’s interesting because our techniques are entirely different. She will think about something but then she’ll free write, she’ll just sit at a computer and write I think this, I think this, I think this. And then that will be vastly compressed, edited, rewritten or whatever until the final thing happens. I will just sit there silently thinking for a very long time and then I’ll write what is almost the final draft. So, a lot of it happens. There might be some scribbles for an outline or something like that but a lot of it is in my brain before it’s on the page."
是的,躲在电脑后面。我的做法……所以,我的妻子詹妮弗是一名科普作家,但这很有趣,因为我们的技术完全不同。她会思考一些事情,但随后她会自由写作,她会坐在电脑前写我想这个,我想这个,我想这个。然后,这些内容将被大量压缩、编辑、重写或其他任何方式,直到最终的事情发生。我会坐在那里默默思考很长一段时间,然后我会写出几乎是最终稿的内容。所以,很多事情都会发生。可能会有一些大纲之类的潦草的内容,但很多内容在写到页面上之前就已经在我的脑海里了。
— Sean Carroll (02:17:42)
"I think we would figure out that language thing pretty quickly. I mean, maybe not as quickly as we do when different human tribes find each other, because obviously there’s a lot of commonalities in humanity. But there is logic in math, and there is the physical world. You can point to a rock and go “rock.” I don’t think it would take that long."
我想我们很快就能弄清楚语言问题。我的意思是,也许不像我们不同的人类部落找到彼此时那么快,因为显然人类有很多共同点。但数学中有逻辑,也有物理世界。你可以指着一块石头然后说“rock”。我认为不会花那么长时间。
— Sean Carroll (00:28:47)
"Yeah, I think they will create better and better simulations. I think the philosopher, David Chalmers, has done what I consider to be a good job of arguing that we should treat things that happen in virtual reality and in simulated realities as just as real as the reality that we experience. I also think that as a practical matter, people will realize how much harder it is to simulate a realistic world than we naively believe. This is not a my lifetime kind of worry. AGI"
是的,我认为他们会创造出越来越好的模拟。我认为哲学家大卫·查尔默斯(David Chalmers)做了我认为很好的工作,他认为我们应该将虚拟现实和模拟现实中发生的事情视为与我们经历的现实一样真实。我还认为,作为一个实际问题,人们会意识到模拟现实世界比我们天真地认为的要困难得多。这不是我一生的担忧。通用人工智能
— Sean Carroll (01:34:34)
"Well, I don’t think it will happen naturally. I think it could happen. Again, I’m not against the principle. But again, the way that large language models came to be and what they’re optimized for is wildly different than the way that human beings came to be and what they’re optimized for. So I think we’re missing a chance to be much more clear-headed about what large language models are by judging them against human beings. Again, both in positive ways and negative ways."
嗯,我认为这不会自然发生。我认为这可能会发生。再说一遍,我并不反对这个原则。但同样,大型语言模型的形成方式及其优化目标与人类的形成方式及其优化目标截然不同。因此,我认为我们错过了一个机会,可以通过将大型语言模型与人类进行比较来更清晰地了解它们是什么。同样,无论是积极的方式还是消极的方式。
— Sean Carroll (01:39:24)
🎙️ 完整对话(557 条)
Lex Fridman (00:00:00)
The whole point of relativity is to say there’s no such thing as right now when you’re far away. That is doubly true for what’s inside a black hole. You might think, “Well, the galaxy is very big.” It’s really not. It’s some tens of thousands of light years across and billions of years old. You don’t need to move at a high fraction of the speed of light to fill the galaxy.
相对论的全部意义在于,当你远离时,不存在“现在”这样的事情。对于黑洞内部的东西来说更是如此。你可能会想,“嗯,银河系很大。”事实并非如此。它的直径约为数万光年,已有数十亿年的历史。你不需要以光速的很大一部分移动来充满银河系。
Lex Fridman (00:00:23)
The number of worlds is …
世界的数量是……
Lex Fridman (00:00:26)
Very big.
很大。
Lex Fridman (00:00:26)
… very, very, very big. Where do those worlds fit, where they go?
……非常非常非常大。这些世界适合在哪里,它们会去哪里?
Lex Fridman (00:00:34)
The short answer is the worlds don’t exist in space. Space exists separately in each world.
简而言之,世界并不存在于太空中。空间分别存在于每个世界中。
Lex Fridman (00:00:48)
The following is a conversation with Sean Carroll. His third time in this podcast. He is a theoretical physicist at Johns Hopkins, host of the Mindscape Podcast that I personally love and highly recommend, and author of many books, including the most recent book series called The Biggest Ideas in the Universe.
以下是与肖恩·卡罗尔的对话。他第三次参加这个播客。他是约翰·霍普金斯大学的理论物理学家,我个人喜欢并强烈推荐的 Mindscape 播客的主持人,也是许多书籍的作者,包括最新的《宇宙中最大的想法》系列丛书。
Lex Fridman (00:01:07)
The first book of which is titled Space, Time, and Motion. It’s on the topic of general relativity. The second coming out on May 14th, you should definitely pre-order it, it’s titled the Quanta and Fields. That one is on the topic of quantum mechanics.
第一本书的标题是《空间、时间和运动》。这是关于广义相对论的主题。第二部将于 5 月 14 日上映,你绝对应该预订它,它的标题是《Quanta and Fields》。那是关于量子力学的主题。
Lex Fridman (00:01:24)
Sean is a legit, active, theoretical physicist and at the same time is one of the greatest communicators of physics ever. I highly encourage you listen to his podcast, read his books, and pre-order the new book to support his work. This was, as always, a big honor and a pleasure for me. This is Lex Fridman Podcast. To support it, please check out our sponsors in the description. Now, dear friends here’s Sean Carroll. General relativity
肖恩是一位正统、活跃的理论物理学家,同时也是有史以来最伟大的物理学传播者之一。我强烈鼓励您收听他的播客,阅读他的书籍,并预订新书以支持他的工作。一如既往,这对我来说是一项巨大的荣誉和快乐。这是莱克斯·弗里德曼播客。为了支持它,请在说明中查看我们的赞助商。现在,亲爱的朋友们
Lex Fridman (00:01:55)
In book one of the series, The Biggest Ideas in the Universe called Space, Time, Motion, you take on classical mechanics, general relativity by taking on the main equation of general relativity and making it accessibly easy to understand. Maybe at the high level, what is general relativity? What’s a good way to start to try to explain it?
在该系列的第一本书《宇宙中最大的思想》《空间、时间、运动》中,您通过采用广义相对论的主要方程并使其易于理解来了解经典力学和广义相对论。也许在高层次上,什么是广义相对论?开始尝试解释它的好方法是什么?
Sean Carroll (00:02:18)
Probably the best way to start to try to explain it is special relativity, which came first, 1905. It was the culmination of many decades of people putting things together. But it was Einstein in 1905. In fact, it wasn’t even Einstein. I should give more credit to Minkowski in 1907. Einstein in 1905 figured out that you could get rid of the ether, the idea of a rest frame for the universe and all the equations of physics would make sense with the speed of light being a maximum.
也许开始尝试解释它的最好方法是狭义相对论,它于 1905 年首次出现。它是几十年来人们将事物组合在一起的顶峰。但那是1905年的爱因斯坦。事实上,那甚至不是爱因斯坦。我应该更多地赞扬 Minkowski 在 1907 年的表现。爱因斯坦在 1905 年发现你可以摆脱以太、宇宙静止框架的想法以及一切
Lex Fridman (00:02:50)
But then it was Minkowski who used to be Einstein’s professor in 1907 who realized the most elegant way of thinking about this idea of Einstein’s was to blend space and time together into spacetime to really imagine that there is no hard and fast division of the four-dimensional world in which we live into space and time separately.
但后来,1907年曾担任爱因斯坦教授的明可夫斯基意识到,思考爱因斯坦这个想法的最优雅的方式是将空间和时间融合在一起成为时空,真正想象我们生活的四维世界并没有严格而快速地划分为空间和时间。
Sean Carroll (00:03:11)
Einstein was at first dismissive of this. He thought it was just like, “Oh, the mathematicians or over-formalizing again.” But then he later realized that if spacetime is a thing, it can have properties and in particular it can have a geometry. It can be curved from place to place. That was what let him solve the problem of gravity.
爱因斯坦起初对此不屑一顾。他认为这就像,“哦,数学家,或者又过度形式化了。”但后来他意识到,如果时空是一个东西,它就可以有属性,特别是它可以有几何形状。它可以从一个地方弯曲到另一个地方。这就是让他解决重力问题的原因。
Sean Carroll (00:03:33)
He had previously been trying to fit in what we knew about gravity from Newtonian mechanics, the inverse square law of gravity, to his new relativistic theory. It didn’t work. The final leap was to say gravity is the curvature of spacetime, and that statement is basically general relativity.
此前,他一直试图将我们从牛顿力学中了解到的引力(引力平方反比定律)融入到他的新相对论中。它不起作用。最后的飞跃是说引力是时空的曲率,这种说法基本上是广义相对论。
Lex Fridman (00:03:54)
The tension with Minkowski was he was a mathematician.
与闵可夫斯基的紧张关系在于他是一名数学家。
Lex Fridman (00:03:56)
Yes.
是的。
Lex Fridman (00:03:57)
It’s the tension between physics and mathematics. In fact, in your lecture about this equation, one of them, you say that Einstein is a better physicist than he gets credit for.
这是物理和数学之间的紧张关系。事实上,在你关于这个方程(其中一个方程)的演讲中,你说爱因斯坦是一位比他所认为的更好的物理学家。
Lex Fridman (00:04:09)
Yep. I know that’s hard. That’s a little bit of a joke there, right?
是的。我知道这很难。这有点开玩笑,对吧?
Lex Fridman (00:04:14)
Yeah.
是的。
Sean Carroll (00:04:15)
Because we all give Einstein a lot of credit. But then we also, partly based on fact, but partly to make ourselves feel better, tell ourselves a story about how later in life, Einstein couldn’t keep up. There were younger people doing quantum mechanics and quantum field theory and particle physics, and he was just unable to really philosophically get over his objections to that.
因为我们都给予爱因斯坦很大的信任。但后来我们也部分基于事实,部分是为了让自己感觉好一点,给自己讲了一个故事,讲述爱因斯坦在后来的生活中如何跟不上的。有一些年轻人在研究量子力学、量子场论和粒子物理学,而他只是无法真正从哲学上克服对此的反对意见。
Sean Carroll (00:04:37)
I think that that story about the latter part is completely wrong, almost 180 degrees wrong. I think that Einstein understood quantum mechanics as well as anyone, at least up through the 1930s. I think that his philosophical objections to it are correct. He should actually have been taken much more seriously about that.
我认为关于后半部分的那个故事是完全错误的,几乎是180度的错误。我认为爱因斯坦和其他人一样理解量子力学,至少在 20 世纪 30 年代是这样。我认为他对此的哲学反对是正确的。他实际上应该对此更加认真地对待。
Lex Fridman (00:04:58)
What he did, what he achieved in trying to think these problems through is to really basically understand the idea of quantum entanglement, which is important these days when it comes to understanding quantum mechanics. Now, it’s true that in the ’40s and ’50s he placed his efforts in hopes for unifying electricity and magnetism with gravity. That didn’t really work out very well.
Sean Carroll (00:05:23)
All of us try things that don’t work out. I don’t hold that against him. But in terms of IQ points, in terms of trying to be a clear-thinking physicist, he was really, really great.
Lex Fridman (00:05:33)
What does greatness look like for a physicist? How difficult is it to take the leap from special relativity to general relativity? How difficult is it to imagine that, to consider spacetime together and to imagine that there’s a curvature to this whole thing?
Sean Carroll (00:05:53)
Yeah. That’s a great question. I think that if you want to make the case for Einstein’s greatness, which is not hard to do, there’s two things you point at. One is in 1905, his famous miracle year, he writes three different papers on three wildly different subjects, all of which would make you famous just for writing that one paper.
Sean Carroll (00:06:17)
Special relativity is one of them. Brownian motion is another one, which is just the little vibrations of tiny little dust specks in the air. But who cares about that? What matters is it proves the existence of atoms. He explains Brownian motion by imagining there are molecules in the air and deriving their properties. Brilliant.
Sean Carroll (00:06:35)
Then he basically starts the world on the road to quantum mechanics with his paper on, which again, is given a boring label of the photoelectric effect. What it really was is he invented photons. He showed that light should be thought of as particles as well as waves. He did all three of those very different things in one year.
Sean Carroll (00:06:55)
Okay. But the other thing that gets him genius status is, like you say, general relativity. This takes 10 years from 1905 to 1915. He wasn’t only doing general relativity. He was working on other things. He invented refrigerator. He did various interesting things. He wasn’t even the only one working on the problem.
Sean Carroll (00:07:13)
There were other people who suggested relativistic theories of gravity. But he really applied himself to it. I think as your question suggests, the solution was not a matter of turning a crank. It was something fundamentally creative. In his own telling of the story, his greatest moment, his happiest moment was when he realized that if the way that we would modern … say it in modern terms, if you were in a rocket ship accelerating at 1G, at acceleration due to gravity, if the rocket ship were very quiet, you wouldn’t be able to know the difference between being in a rocket ship and being on the surface of the earth.
Sean Carroll (00:07:55)
Gravity is not detectable or at least not distinguishable from acceleration. Number one, that’s a pretty clever thing to think. But number two, if you or I had had that thought, we would’ve gone, “Huh. We’re pretty clever.” He reasons from there to say, “Okay. If gravity is not detectable, then it can’t be like an ordinary force.”
Lex Fridman (00:08:17)
The electromagnetic force is detectable. We can put charged particles around. Positively charged particles and negatively charged particles respond differently to an electric field or to a magnetic field. He realizes that what his thought experiment showed, or at least suggested, is that gravity isn’t like that. Everything responds in the same way to gravity. How could that be the case?
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