(Music) The basic question is, does life exist beyond Earth? Scientists who are called astrobiologists are trying to find that out right now. Most astrobiologists are trying to figure out if there's microbial life on Mars, or in the ocean under the frozen surface of Jupiter's moon Europa, or in the liquid hydrocarbon lakes that we've found on Saturn's moon Titan. But one group of astrobiologists works on SETI. SETI is the Search for Extraterrestrial Intelligence, and SETI researchers are trying to detect some evidence that intelligent creatures elsewhere have used technology to build a transmitter of some sort. But how likely is it that they will manage to find a signal? There are certainly no guarantees when it comes to SETI, but something called the Drake equation, named after Frank Drake, can help us organize our thinking about what might be required for successful detection. If you've dealt with equations before, then you probably expect that there will be a solution to the equation, a right answer. The Drake equation, however, is different, because there are so many unknowns. It has no right answer. As we learn more about our universe and our place within it, some of the unknowns get better known, and we can estimate an answer a bit better. But there won't be a definite answer to the Drake equation until SETI succeeds or something else proves that Earthlings are the only intelligent species in our portion of the cosmos. In the meantime, it is really useful to consider the unknowns. The Drake equation attempts to estimate the number of technological civilizations in the Milky Way Galaxy -- we call that N -- with whom we could make contact, and it's usually written as: N equals R-star multiplied by f-sub-p multiplied by n-sub-e multiplied by f-sub-l multiplied by f-sub-i multiplied by f-sub-c and lastly, multiplied by capital L. All those factors multiplied together help to estimate the number of technological civilizations that we might be able to detect right now. R-star is the rate at which stars have been born in the Milky Way Galaxy over the last few billion years, so it's a number that is stars per year. Our galaxy is 10 billion years old, and early in its history stars formed at a different rate. All of the f-factors are fractions. Each one must be less than or equal to one. F-sub-p is the fraction of stars that have planets. N-sub-e is the average number of habitable planets in any planetary system. F-sub-l is the fraction of planets on which life actually begins and f-sub-i is the fraction of all those life forms that develop intelligence. F-sub-c is the fraction of intelligent life that develops a civilization that decides to use some sort of transmitting technology. And finally, L -- the longevity factor. On average, how many years do those transmitters continue to operate? Astronomers are now almost able to tell us what the product of the first three terms is. We're now finding exoplanets almost everywhere. The fractions dealing with life and intelligence and technological civilizations are ones that many, many experts ponder, but nobody knows for sure. So far, we only know of one place in the universe where life exists, and that's right here on Earth. In the next couple of decades, as we explore Mars and Europa and Titan, the discovery of any kind of life there will mean that life will be abundant in the Milky Way. Because if life originated twice within this one Solar System, it means it was easy, and given similar conditions elsewhere, life will happen. So the number two is a very important number here. Scientists, including SETI researchers, often tend to make very crude estimates and acknowledge that there are very large uncertainties in these estimates, in order to make progress. We think we know that R-star and n-sub-e are both numbers that are closer to 10 than, say, to one, and all the f-factors are less than one. Some of them may be much less than one. But of all these unknowns, the biggest unknown is L, so perhaps the most useful version of the Drake equation is simply to say that N is approximately equal to L. The information in this equation is very clear. Unless L is large, N will be small. But, you know, you can also turn that around. If SETI succeeds in detecting a signal in the near future, after examining only a small portion of the stars in the Milky Way, then we learn that L, on average, must be large. Otherwise, we couldn't have succeeded so easily. A physicist named Philip Morrison summarizes by saying that SETI is the archaeology of the future. By this, he meant that because the speed of light is finite, any signals detected from distant technologies will be telling us about their past by the time they reach us. But because L must be large for a successful detection, we also learn about our future, particularly that we can have a long future. We've developed technologies that can send signals into space and humans to the moon, but we've also developed technologies that can destroy the environment, that can wage war with weapons and biological terrorism. In the future, will our technology help stabilize our planet and our population, leading to a very long lifetime for us? Or will we destroy our world and its inhabitants after only a brief appearance on the cosmic stage? I encourage you to consider the unknowns in this equation. Why don't you make your own estimates for these unknowns, and see what you come up with for N? Compare that with the estimates made by Frank Drake, Carl Sagan, other scientists or your neighbors. Remember, there's no right answer. Not yet.
(音乐) 我们的基本问题是, 地球之外还存在生命吗? 那些被叫作天体生物学家的科学家们 正在尝试研究这个问题。 许多天体生物学家正在试图确定 在火星上, 或者在木星的海洋冰面之下, 又或者是在液态烃湖中, 是否存在微生物, (我们已在土星的卫星“提坦”上发现液态烃湖)。 但一个天体生物学家小组 正致力于 SETI 研究。 SETI 是指对外星智能探索, SETI 研究者正尝试发掘一些证据 来说明除了智能生物之外的其他生物 已经使用科技建造了某种发射器。 但是他们想法设法发现信号的 可能性有多大? 没有 SETI 能勘测到信号的绝对保证, 不过有个东西叫德雷克方程, 由法兰克•德雷克命名, 可以帮我们整理思路: 成功的探测 究竟需要什么。 如果你之前已经处理过方程 那么你可能会期待 这个方程会有一种解法 可得出正确答案。 然而,德雷克方程是截然不同的。 因为有许多未知数。 它没有正确答案。 随着我们对宇宙 以及我们所处在的土地了解越来越多 一些未知数将会得到更好的理解, 我们可以预估一个更好的答案。 但是德雷克方程将不会有明确的答案 直到 SETI 成功 或者其他事情能够证明 地球人是宇宙中唯一的智能物种。 同时, 考虑未知数极为有用。 德雷克方程试图预测 科技文明社会的数量 在银河系中——我们叫它N—— 我们将能和谁联系, 这常常被写作: N 等于 R 星 乘以 f-sub-p 乘以 n-sub-e 乘以 f-sub-l 乘以f-sub-i 乘以 f-sub-c 最后,乘以大写 L. 所有这些因素乘在一起 可以帮助预测 科技文明的数量 这也许是我们目前能够做的。 R 星是一种比率, 星星已经在银河系诞生了 几十亿年, 所以这是指星星每年诞生的数量。 我们的银河系已有几百亿岁, 在它的历史早期 星星就已经形成了不同的比率。 所有的 f 因素都是其中一部分。 每个因素都必须小于或等于另一个, f-sub-p 是指具有行星的星星。 n-sub-e 是指在任何一个行星系统中的 可居住行星的平均数量。 f-sub-l 是指开始有生命的行星。 而 f-sub-i 是指那些所有 能够发展智力的生命。 f-sub-c 是指 能够发展文明的智能生命, 它们能决定运用某种类型的传输技术。 最后,L 是指 寿命因素。 平均来说,那些传输器 能够持续运作多少年? 天文学家现在几乎能够 告诉我们前三种术语分别是什么。 我们正在尽可能四处探索外星行星。 有无数的专家正在研究 那些孕育生命、智能 与技术文明的行星, 但是没有人能完全了解。 到目前为止, 我们仅知道宇宙中有一个地方 有生命存在, 那个地方,毫无疑问,就是地球。 在接下來的几十年, 随着我们对火星、木星以及提坦的探索, 任何物种的发现 都意味着银河系 将会有丰富多样的生命。 因为如果生命在这个太阳系内 起源了两次, 那么这意味着生命起源很容易, 并假设别的地方也有相似条件, 生命就会产生。 所以二这个数字在这里尤其重要。 科学家,包括 SETI 研究者, 经常想要做一些大致预测, 并承认在这些预测中会有巨大的未知数, 以获取进展。 我们认为我们了解 R 星和 n-sub-e 都是 比 10 更接近 1 的参数, 并且这些 f 因素都小于 1, 其中一些可能要远远小于 1。 但在这些未知数中, 最大的未知数是 L, 所以可能德雷克方程最有用的版本 可以简单地说是 N 近似于 L。 这方程式的信息十分清晰。 除非L是较大的参数, N就是较小的参数。 但是你也可以把推论倒过来。 如果 SETI 在不远的将来探测信号成功, 验证到银河系的行星中 只有一个小样本, 那么我们可以得出, L 通常一定是较大的参数。 不然,我们不可能如此容易成功。 一个叫菲利普•莫里森的物理学家 总结说 SEIT 是对未来的考古学。 通过这个观点他想表达 因为光速是有限的, 任何从远传技术探测到的信号 将会在传输到我们这儿时, 告诉我们它们的过去。 但是因为对于一个成功的探测而言, L 一定是较大的参数, 所以我们还会了解到我们的未来, 尤其是我们可能会拥有 一个很长远的未来。 我们已经发展出 能发送信号到太空的科技, 并且能将人类送上月球, 但是我们也发展出了能够破坏环境的科技, 利用武器以及生物恐怖主义 发动战争。 在未来, 我们的科技能帮助我们稳定星球 以及人口, 从而使我们更长寿吗? 又或者,我们将会宇宙舞台短暂的出现后 毁掉我们的世界及其居民? 我鼓励你们去思考 这个方程式里的未知数。 为什么你们不为这些未知数 做一些自己的预测, 然后看看你将如何解决 N? 将这些预测与弗兰克·德雷克、 卡尔·萨根、其他科学家, 或者你邻居的预测比较。 记住,没有标准答案。 至少目前还没有。