How do you observe something you can't see? This is the basic question of somebody who's interested in finding and studying black holes. Because black holes are objects whose pull of gravity is so intense that nothing can escape it, not even light, so you can't see it directly.
如何观察那些你看不见的东西? 对于有兴趣寻找和研究黑洞的人来说, 这是个根本问题。 因为黑洞的引力极为强大, 任何物体 包括光线,都不能逃脱。 所以你不能直接看到它。
So, my story today about black holes is about one particular black hole. I'm interested in finding whether or not there is a really massive, what we like to call "supermassive" black hole at the center of our galaxy. And the reason this is interesting is that it gives us an opportunity to prove whether or not these exotic objects really exist. And second, it gives us the opportunity to understand how these supermassive black holes interact with their environment, and to understand how they affect the formation and evolution of the galaxies which they reside in.
我今天要讲的黑洞 是关于一种特别的黑洞。 我的兴趣在于是否 存在一个特别巨大,我们称之为“超大质量黑洞” 的黑洞存在银河系中心。 感兴趣的原因是 这将给我们一个机会去证明 是否这些奇特的物体是否真的存在。 其次,这给我们一个机会 去了解这些特大质量黑洞是如何 与他们的环境进行互动, 以及它们是如何影响到 所处宇宙的形成和演化
So, to begin with, we need to understand what a black hole is so we can understand the proof of a black hole. So, what is a black hole? Well, in many ways a black hole is an incredibly simple object, because there are only three characteristics that you can describe: the mass, the spin, and the charge. And I'm going to only talk about the mass. So, in that sense, it's a very simple object. But in another sense, it's an incredibly complicated object that we need relatively exotic physics to describe, and in some sense represents the breakdown of our physical understanding of the universe.
言归正传, 首先,我们必须理解黑洞是什么, 这样我们才能理解黑洞存在的证据。 那么,黑洞是什么? 从很多方面来说,黑洞是个简单到不可思议的物体, 它只有三个特征可以测量: 质量 角动量和电荷。 而我将只讨论质量。 从这个意义上来说,它是非常简单的物体。 但是,换个角度,它又是极其复杂的, 以至于我们需要相对来说比较奇特的物理学来描述, 在某种程度上还标识着我们对于宇宙的的物理认知的崩溃。 ()
But today, the way I want you to understand a black hole, for the proof of a black hole, is to think of it as an object whose mass is confined to zero volume. So, despite the fact that I'm going to talk to you about an object that's supermassive, and I'm going to get to what that really means in a moment, it has no finite size. So, this is a little tricky.
如今,为了让你了解黑洞 了解黑洞存在的证据, 是把它看作一个 质量为零的物体 尽管我将和你们谈谈关于 超质量的物体 而对于这个物体,我将在后面进行阐述 它没有大小。 这有点棘手。
But fortunately there is a finite size that you can see, and that's known as the Schwarzschild radius. And that's named after the guy who recognized why it was such an important radius. This is a virtual radius, not reality; the black hole has no size. So why is it so important? It's important because it tells us that any object can become a black hole. That means you, your neighbor, your cellphone, the auditorium can become a black hole if you can figure out how to compress it down to the size of the Schwarzschild radius.
但幸运的是你可以看到有限的大小, 这被称为史瓦西半径 它命名于史瓦西 他发现了为什么这个半径是如此重要 这是一个虚拟的半径,而不是真实的;黑洞没有大小 那么,为什么这很重要呢? 它重要是因为它告诉我们 任何物体都可以成为黑洞 这意味着你的邻居,你的手机, 还有礼堂都能成为黑洞 如果你能弄明白 如何把它压缩至史瓦西半径大小。
At that point, what's going to happen? At that point gravity wins. Gravity wins over all other known forces. And the object is forced to continue to collapse to an infinitely small object. And then it's a black hole. So, if I were to compress the Earth down to the size of a sugar cube, it would become a black hole, because the size of a sugar cube is its Schwarzschild radius.
在这一点上,会发生什么? 在这一点上,引力获胜。 引力胜过其他所有已知力量 物体被迫继续坍塌 成为一个奇点。 这就是黑洞。 如果把地球压缩至一块方糖大小, 地球就会成为一个黑洞 因为方糖的大小是它的史瓦西半径。
Now, the key here is to figure out what that Schwarzschild radius is. And it turns out that it's actually pretty simple to figure out. It depends only on the mass of the object. Bigger objects have bigger Schwarzschild radii. Smaller objects have smaller Schwarzschild radii. So, if I were to take the sun and compress it down to the scale of the University of Oxford, it would become a black hole.
现在,关键是要弄清楚什么是史瓦西半径。 事实证明,这很容易算出来 它只依赖于物体的质量。 更大的物体有更大的是史瓦西半径。 更小的物体有更小的史瓦西半径。 因此,如果我把太阳 压缩至英国牛津大学的大小, 太阳会成为一个黑洞。
So, now we know what a Schwarzschild radius is. And it's actually quite a useful concept, because it tells us not only when a black hole will form, but it also gives us the key elements for the proof of a black hole. I only need two things. I need to understand the mass of the object I'm claiming is a black hole, and what its Schwarzschild radius is. And since the mass determines the Schwarzschild radius, there is actually only one thing I really need to know.
现在,我们知道了什么是史瓦希半径。 它实际上是一个相当有用的概念, 因为它不仅告诉我们 黑洞何时形成, 同时还带给我们黑洞存在证据的关键要素。 我只需要两件东西。 我需要了解物体的质量 我自称是一个黑洞, 以及其史瓦西半径。 由于质量决定史瓦西半径, 实际上只有一件事我需要知道。
So, my job in convincing you that there is a black hole is to show that there is some object that's confined to within its Schwarzschild radius. And your job today is to be skeptical. Okay, so, I'm going to talk about no ordinary black hole; I'm going to talk about supermassive black holes.
因此,我的工作是说服你 那有一个黑洞, 表明有一些物体 仅限于其史瓦西半径· 而你要做的是对此表示怀疑。 好了,我要谈的不是常规黑洞; 我要谈论的是超大质量黑洞。
So, I wanted to say a few words about what an ordinary black hole is, as if there could be such a thing as an ordinary black hole. An ordinary black hole is thought to be the end state of a really massive star's life. So, if a star starts its life off with much more mass than the mass of the Sun, it's going to end its life by exploding and leaving behind these beautiful supernova remnants that we see here. And inside that supernova remnant is going to be a little black hole that has a mass roughly three times the mass of the Sun. On an astronomical scale that's a very small black hole.
因此,我要说常规黑洞是什么 好像有这样一个可以作为常规黑洞的东西。 一个常规黑洞可以被看作是 大质量恒星生命的晚期。 因此,当一个恒星消亡 而这个恒星的质量远大于太阳 它将以爆炸结束生命 我们将会看到留下的超新星遗骸 在超新星遗骸的内部 形成一个小型黑洞 质量大概是太阳的3倍。 从天文学的角度来看 这是一个非常小的黑洞
Now, what I want to talk about are the supermassive black holes. And the supermassive black holes are thought to reside at the center of galaxies. And this beautiful picture taken with the Hubble Space Telescope shows you that galaxies come in all shapes and sizes. There are big ones. There are little ones. Almost every object in that picture there is a galaxy. And there is a very nice spiral up in the upper left. And there are a hundred billion stars in that galaxy, just to give you a sense of scale. And all the light that we see from a typical galaxy, which is the kind of galaxies that we're seeing here, comes from the light from the stars. So, we see the galaxy because of the star light.
现在,我想谈谈超大质量黑洞。 超大质量黑洞被认为位于星系中心。 这幅美丽的图片是哈勃太空望远镜拍摄的 展示了星系的所有形状和大小。 有大的,有小的。 几乎图片上的每一个物体都是一个星系。 有一个非常漂亮的螺旋臂在左上角。 有100亿颗恒星在那个星系中, 仅仅给你一种规模感。 我们从一个典型的星系中看到的所有光线, 是我们在这儿看到的星系中的一种, 来自恒星的光线。 我们看见星系是因为恒星的光。
Now, there are a few relatively exotic galaxies. I like to call these the prima donna of the galaxy world, because they are kind of show offs. And we call them active galactic nuclei. And we call them that because their nucleus, or their center, are very active. So, at the center there, that's actually where most of the starlight comes out from. And yet, what we actually see is light that can't be explained by the starlight. It's way more energetic. In fact, in a few examples it's like the ones that we're seeing here. There are also jets emanating out from the center. Again, a source of energy that's very difficult to explain if you just think that galaxies are composed of stars.
有一些比较奇特的星系 我喜欢称这些星系为女主角, 因为它们特别愿意展示自己 我们称之为活跃星系核心。 我们之所以这样称呼是因为它们的核心, 或者它们的中心,非常活跃。 在中心位置, 大部分星光是从那发出的。 然而,事实上我们看到的是 无法用星光来解释的光 它比星光更有活力。 事实上,下面的例子中跟我们现在看的这些有些相似。 也是从中心喷射出。 如果你仅仅认为星系是由恒星组成的 那这股能量的来源就很难解释了。
So, what people have thought is that perhaps there are supermassive black holes which matter is falling on to. So, you can't see the black hole itself, but you can convert the gravitational energy of the black hole into the light we see. So, there is the thought that maybe supermassive black holes exist at the center of galaxies. But it's a kind of indirect argument.
人们认为 也许有超大质量黑洞 所以物质被吸引过去。 你不能看见黑洞本身, 但是你能将黑洞的引力 转换为我们能见的光。 因此,有一种想法就是 也许超大质量黑洞存在于星系的中心。 但这仅是一种间接论据。
Nonetheless, it's given rise to the notion that maybe it's not just these prima donnas that have these supermassive black holes, but rather all galaxies might harbor these supermassive black holes at their centers. And if that's the case -- and this is an example of a normal galaxy; what we see is the star light. And if there is a supermassive black hole, what we need to assume is that it's a black hole on a diet. Because that is the way to suppress the energetic phenomena that we see in active galactic nuclei.
尽管如此,这却带来了一种概念 也许不仅是这些主角 有超大质量黑洞 而是所有的星系中心 都有可能藏匿超大质量黑洞 如果是这种情况——这是一个常规星系的例子; 我们看到的是星光。 如果有超大质量黑洞, 我们需要假设的是它是一个正在节食的黑洞。 因为这是一种我们所见到的压制现象 在活跃星系的核心
If we're going to look for these stealth black holes at the center of galaxies, the best place to look is in our own galaxy, our Milky Way. And this is a wide field picture taken of the center of the Milky Way. And what we see is a line of stars. And that is because we live in a galaxy which has a flattened, disk-like structure. And we live in the middle of it, so when we look towards the center, we see this plane which defines the plane of the galaxy, or line that defines the plane of the galaxy.
如果我们要在星系中心找寻 这些隐藏的黑洞, 最好的地方就是我们所在的星系,银河系。 这是一张银河系中心的 大范围图片 我们看到的是线状的恒星系。 因为我们所在的星系 是一个扁平的,盘状结构的星系。 而且我们居住在中央,因此当我们看向中心, 我们把这个平面看成是星系的平面, 或者把这条线看成是星系的平面
Now, the advantage of studying our own galaxy is it's simply the closest example of the center of a galaxy that we're ever going to have, because the next closest galaxy is 100 times further away. So, we can see far more detail in our galaxy than anyplace else. And as you'll see in a moment, the ability to see detail is key to this experiment.
研究我们自己的星系的优势是 在我们接触过的星系中心的实体中 这是距离我们最近的星系 我们的邻居星系距离我们则足有100倍的距离 因此,对我们自身所在星系的研究可以做到比其他任何一个星体 都更加透彻 就像我们马上就要谈到的 观察细节的能力对于我们这次实验至关重要
So, how do astronomers prove that there is a lot of mass inside a small volume? Which is the job that I have to show you today. And the tool that we use is to watch the way stars orbit the black hole. Stars will orbit the black hole in the very same way that planets orbit the sun. It's the gravitational pull that makes these things orbit. If there were no massive objects these things would go flying off, or at least go at a much slower rate because all that determines how they go around is how much mass is inside its orbit.
这样一来 宇航员如何才能证明一个相对小的空间内存在很大的质量呢 这正是我今天想要向大家展示的 我们将应用的工具就是 观测行星环绕黑洞的轨道 行星环绕的黑洞的轨道 与行星环绕太阳类似 是重心牵引力 使这些星体按照轨道运行 如果没有大质量的物体存在,这些星体都将四散而出 或者说至少运动的速率对大幅下降 这是因为,对它们如何运动起到决定性作用的是 它的轨道内部存在多少的物质
So, this is great, because remember my job is to show there is a lot of mass inside a small volume. So, if I know how fast it goes around, I know the mass. And if I know the scale of the orbit I know the radius. So, I want to see the stars that are as close to the center of the galaxy as possible. Because I want to show there is a mass inside as small a region as possible. So, this means that I want to see a lot of detail. And that's the reason that for this experiment we've used the world's largest telescope.
我们必须要清楚这一点,因为我的工作就是 证明一个小的空间内也存在大量的物质 因此,如果可以计算出它的运行速度,我便可以推断出质量 更进一 步,如果可以知道轨道的范围,我们就可以计算出其半径 这就是我希望可以尽可能选择 接近星系中心星体的原因 只有这样,我才能在尽可能小的空间内证实物质的存在 也就说明,我需要观测大量的细节数据 这就是我们为何采用世界上最大的望远镜 来做这个实验的原因
This is the Keck observatory. It hosts two telescopes with a mirror 10 meters, which is roughly the diameter of a tennis court. Now, this is wonderful, because the campaign promise of large telescopes is that is that the bigger the telescope, the smaller the detail that we can see. But it turns out these telescopes, or any telescope on the ground has had a little bit of a challenge living up to this campaign promise. And that is because of the atmosphere. Atmosphere is great for us; it allows us to survive here on Earth. But it's relatively challenging for astronomers who want to look through the atmosphere to astronomical sources.
这是keck天文台,它拥有2台镜头有10米长的望远镜 差不多 是一个网球场直径的长度 这一点很赞 因为大型望远镜总是承诺 望远镜越大 我们能观察到越小的细节。 然而,我们却发现这些或现有的所有望远镜 都与预期的表现有所差距 这是因为大气环境 地球大气层对我们人类至关重要 它保证了生命的存在 但是对天文学家来说,它却是相对有挑战性的, 因为他们需要透过大气层来观测外部的世界
So, to give you a sense of what this is like, it's actually like looking at a pebble at the bottom of a stream. Looking at the pebble on the bottom of the stream, the stream is continuously moving and turbulent, and that makes it very difficult to see the pebble on the bottom of the stream. Very much in the same way, it's very difficult to see astronomical sources, because of the atmosphere that's continuously moving by.
因此,为了让大家更好的理解 我用一个比喻 就像看一块小溪底的鹅卵石一样 在看河底的鹅卵石时 溪水不断流动 使得观察底部的鹅卵石变的很困难 同样的 正是因为大气层不停的流动 我们很难观测到清晰的外层
So, I've spent a lot of my career working on ways to correct for the atmosphere, to give us a cleaner view. And that buys us about a factor of 20. And I think all of you can agree that if you can figure out how to improve life by a factor of 20, you've probably improved your lifestyle by a lot, say your salary, you'd notice, or your kids, you'd notice.
因此我花费了职业生涯中很长的时间来研究如何克服这一困难 来给大家带来一个更清晰的视野 这可以提高我们1/20的成功率 我认为我们大家都认同这一点 如果可以提高生活质量1/20的水平 那么整体的生活水平将获得很大的改善 拿薪水,或者你的孩子做个例子,你就会发现
And this animation here shows you one example of the techniques that we use, called adaptive optics. You're seeing an animation that goes between an example of what you would see if you don't use this technique -- in other words, just a picture that shows the stars -- and the box is centered on the center of the galaxy, where we think the black hole is. So, without this technology you can't see the stars. With this technology all of a sudden you can see it. This technology works by introducing a mirror into the telescope optics system that's continuously changing to counteract what the atmosphere is doing to you. So, it's kind of like very fancy eyeglasses for your telescope.
这个动画展示了 自适应光学的应用例子 你可以看到一个动画呈现 一幅你只有不应用这个技术才可以看到的画面 换句话说,就是一幅星象图 这个方块位于整个星系的中心 也就是黑洞的所在 因此,如果没有这项技术,我们无法看到星体 应用这项技术我们可以突然的看到它们 这项技术在望远镜的光学系统中增加了一块反光镜 并通过这种原理进行工作 这将持续的改变你对大气层作用的看法 因此,这就像给你的望远镜带上一付花式眼镜
Now, in the next few slides I'm just going to focus on that little square there. So, we're only going to look at the stars inside that small square, although we've looked at all of them. So, I want to see how these things have moved. And over the course of this experiment, these stars have moved a tremendous amount. So, we've been doing this experiment for 15 years, and we see the stars go all the way around.
现在,接下的几幅幻灯片中,我们将主要观察 那个小方块 我们将集中观测方块内部的星体 尽管我们已经观察到了全部 我希望观测它们是如何运动的 这个的实验过程中 星体都运行了相当惊人的距离 我们做这个实验已经进行了15年 我们了解这些星体的运行轨迹
Now, most astronomers have a favorite star, and mine today is a star that's labeled up there, SO-2. Absolutely my favorite star in the world. And that's because it goes around in only 15 years. And to give you a sense of how short that is, the sun takes 200 million years to go around the center of the galaxy. Stars that we knew about before, that were as close to the center of the galaxy as possible, take 500 years. And this one, this one goes around in a human lifetime. That's kind of profound, in a way.
多数的天文学家都有自己最喜欢的一颗星 而我今天的最爱则是上边那棵标志着SO-2的星体 这棵星毫无疑问是我的最爱 这是因为它的运行周期是15年 为了表明这是一段极短的时间 我想说的是太阳需要200亿年才能环绕星系一周 我们以前所了解的尽可能的靠近星系中心的星体 需要500年来完成同样的环绕 然而这一颗星,可以在一个人的生命中就完成环绕 这也可以看成是另类的深邃吧
But it's the key to this experiment. The orbit tells me how much mass is inside a very small radius. So, next we see a picture here that shows you before this experiment the size to which we could confine the mass of the center of the galaxy. What we knew before is that there was four million times the mass of the sun inside that circle. And as you can see, there was a lot of other stuff inside that circle. You can see a lot of stars. So, there was actually lots of alternatives to the idea that there was a supermassive black hole at the center of the galaxy, because you could put a lot of stuff in there.
这一点是这次实验的关键 运行轨道能可以告诉我在一个短半径内究竟存在多少物质 因此,接下来我们将看一幅照片 它展示了在这个实验之前,我们能够 证实这个星系中心的物质的大小 我们之前所了解到的是有 超过太阳四亿倍的质量 我们可以看到,这个轨道内还有很多其它的东西 有很多的星体。 所以,对于星系中心存在着巨大黑洞的假设 也就存在了很多可能性, 因为你可以假设各种各样的物质的存在
But with this experiment, we've confined that same mass to a much smaller volume that's 10,000 times smaller. And because of that, we've been able to show that there is a supermassive black hole there. To give you a sense of how small that size is, that's the size of our solar system. So, we're cramming four million times the mass of the sun into that small volume.
但是通过这次实验 我们证明了在小一些空间的同样的物质 缩小了1万倍 正因为如此,我们才能看到 存在着一个巨型黑洞 究竟有多小 这是太阳系的大小 我们把4亿倍太阳物质 塞进这个小空间里
Now, truth in advertising. Right? I have told you my job is to get it down to the Schwarzchild radius. And the truth is, I'm not quite there. But we actually have no alternative today to explaining this concentration of mass. And, in fact, it's the best evidence we have to date for not only existence of a supermassive black hole at the center of our own galaxy, but any in our universe. So, what next? I actually think this is about as good as we're going to do with today's technology, so let's move on with the problem.
真相出现 我曾说过我的工作是要把它缩小到史瓦西半径的范围 但事实上,我还没有达到那个程度 但是我们目前为止已经没有其它更好的方法 来解释物质的聚集程度 事实上,这是我们目前所拥有的最好的证据 不仅因为我们星系中存在的巨大黑洞 在我们的整个宇宙也存在 下一步是什么呢 我曾经想过这一切都关于我们如何更好的应用现有的科技手段 因此让我们来继续这个问题
So, what I want to tell you, very briefly, is a few examples of the excitement of what we can do today at the center of the galaxy, now that we know that there is, or at least we believe, that there is a supermassive black hole there. And the fun phase of this experiment is, while we've tested some of our ideas about the consequences of a supermassive black hole being at the center of our galaxy, almost every single one has been inconsistent with what we actually see. And that's the fun.
简而言之,我想说的是 这几个例子 代表着我们今天所能达到的水平 在星系的中心,现在我们确认 或者说至少我们相信 存在一个巨型黑洞 这次实验的有趣之处就在于 在我们测试 有关巨型黑洞位于星系中心的后果 的新想法时 基本上任何一个新想法 都没有局限在我们所能看到的 这就是乐趣所在
So, let me give you the two examples. You can ask, "What do you expect for the old stars, stars that have been around the center of the galaxy for a long time, they've had plenty of time to interact with the black hole." What you expect there is that old stars should be very clustered around the black hole. You should see a lot of old stars next to that black hole.
现在我将给出2个例子 你可以问 “你对那些很古老的星体,那些已经围绕星系中心很久的星体 有足够长的时间与黑洞产生互动的那些有什么预期。” 你所期望看到的是 那些古老的星体应该环绕在黑洞附近逐渐接近 你将可以看到黑洞附近聚集很多星体
Likewise, for the young stars, or in contrast, the young stars, they just should not be there. A black hole does not make a kind neighbor to a stellar nursery. To get a star to form, you need a big ball of gas and dust to collapse. And it's a very fragile entity. And what does the big black hole do? It strips that gas cloud apart. It pulls much stronger on one side than the other and the cloud is stripped apart. In fact, we anticipated that star formation shouldn't proceed in that environment.
相似的或者相反的,对于年轻的星体, 它们则不应该出现在那个地方 黑洞不会是恒星摇篮的好邻居 一个星体的形成需要大量的气体与尘埃的崩溃与聚合 它是一个非常脆弱的个体 黑洞在这起到什么作用呢 它可以将气云剥离 它对一面起到更大的拉力 从而把气云剥离 事实上 我们预测 星体的形成不应该在那种环境下发生
So, you shouldn't see young stars. So, what do we see? Using observations that are not the ones I've shown you today, we can actually figure out which ones are old and which ones are young. The old ones are red. The young ones are blue. And the yellow ones, we don't know yet. So, you can already see the surprise. There is a dearth of old stars. There is an abundance of young stars, so it's the exact opposite of the prediction.
所以你不应看到年轻的星体 那么我们到底看到了什么 使用其它一些观察设施 我们可以发现年老或者年轻的星体 年长的星体呈现红色 而年轻的星体则是蓝色 至于黄色的星体,我们还未知 你应该也已经感到很吃惊了 年长的星体很少 却有着很多的年轻星体 这与我们的预测恰恰相反
So, this is the fun part. And in fact, today, this is what we're trying to figure out, this mystery of how do you get -- how do you resolve this contradiction. So, in fact, my graduate students are, at this very moment, today, at the telescope, in Hawaii, making observations to get us hopefully to the next stage, where we can address this question of why are there so many young stars, and so few old stars. To make further progress we really need to look at the orbits of stars that are much further away. To do that we'll probably need much more sophisticated technology than we have today.
这也是有趣的地方 事实上 这也是我们试图揭开的一个谜团 一个有关 我们如何可以解决这个完全相反的结论 所以实际上,我的硕士生们 正在夏威夷的天文观测站 进行观测 希望能我们可以很快的进入下一个阶段 那时我们将重新阐释这个问题 也就是为什么有这么多的年轻星体 而老年星体则如此稀少 为了进一步的研究 我们必须要观测运行轨道 那些更远星体的运行轨道 为了做到一点我们将会需要 更成熟的技术
Because, in truth, while I said we're correcting for the Earth's atmosphere, we actually only correct for half the errors that are introduced. We do this by shooting a laser up into the atmosphere, and what we think we can do is if we shine a few more that we can correct the rest. So this is what we hope to do in the next few years. And on a much longer time scale, what we hope to do is build even larger telescopes, because, remember, bigger is better in astronomy.
因为事实上 当我说到我们正在针对地球大气层进行调节时 我们仅仅 更正差不多半数的错误 我们通过向大气层发射激光来做到这一点 同时 我们也认为 通过这种做法我们可以继续更正剩余的错误 这是我们希望将在接下来几年里完成的人物 更长的一段时间内 我们希望建成更大更精确的观测望远镜 因为在天文学里,大意味着好
So, we want to build a 30 meter telescope. And with this telescope we should be able to see stars that are even closer to the center of the galaxy. And we hope to be able to test some of Einstein's theories of general relativity, some ideas in cosmology about how galaxies form. So, we think the future of this experiment is quite exciting.
我们希望可以建出一部30米天文望远镜 一旦实现 我们将通过它 更好的观测更近距离的星体 与此同时我们也可以 证实爱因斯坦的广义相对论 有关星系是如何形成的宇宙学的一些观点。 我们认为未来我们将做的实验 会非常的令人惊奇
So, in conclusion, I'm going to show you an animation that basically shows you how these orbits have been moving, in three dimensions. And I hope, if nothing else, I've convinced you that, one, we do in fact have a supermassive black hole at the center of the galaxy. And this means that these things do exist in our universe, and we have to contend with this, we have to explain how you can get these objects in our physical world.
作为结论 我将展示一个3D动画 呈现 这些轨道是如何移动的 我希望,哪怕没有任何别的 我至少成功的说服了你们 在星系的中心确实有一个巨型黑洞 这意味着这些物质的确存在在我们的宇宙中 我们必须要承认这一点 我们需要解释如何可以将那些物质引用到我们的物理世界
Second, we've been able to look at that interaction of how supermassive black holes interact, and understand, maybe, the role in which they play in shaping what galaxies are, and how they work.
第二点 巨型黑洞之间 是如何产生影响的 如果可能的话 尽可能的理解它们在形成星系的过程中 所扮演的角色以及这过原理
And last but not least, none of this would have happened without the advent of the tremendous progress that's been made on the technology front. And we think that this is a field that is moving incredibly fast, and holds a lot in store for the future. Thanks very much. (Applause)
最后 如果没有令人震惊的进展 使得科学前沿不断的进步 这一切的成就都不可能达成 我们认为这是一个不断快速发展的领域 未来的发展不可限量 非常感谢 (掌声)