时间:2019-02-16 作者:英语课 分类:英语语言学习


英语课
The advances that have taken place in astronomy, cosmology and biology, in the last 10 years, are really extraordinary -- to the point where we know more about our universe and how it works than many of you might imagine. But there was something else that I've noticed as those changes were taking place, as people were starting to find out that hmm ... yeah, there really is a black hole at the center of every galaxy 1. The science writers and editors -- I shouldn't say science writers, I should say people who write about science -- and editors would sit down over a couple of beers, after a hard day of work, and start talking about some of these incredible perceptions about how the universe works.
And they would inevitably 2 end up in what I thought was a very bizarre place, which is ways the world could end very suddenly. And that's what I want to talk about today. (Laughter) Ah, you laugh, you fools. (Laughter)
(Voice: Can we finish up a little early?)
(Laughter) Yeah, we need the time!
Stephen Petranek: At first, it all seemed a little fantastical to me, but after challenging a lot of these ideas, I began to take a lot of them seriously. And then September 11 happened, and I thought, ah, God, I can't go to the TED 3 conference and talk about how the world is going to end. Nobody wants to hear that. Not after this! And that got me into a discussion with some other people, other scientists, about maybe some other subjects, and one of the guys I talked to, who was a neuroscientist, said, "You know, I think there are a lot of solutions to the problems you brought up," and reminds me of Michael's talk yesterday and his mother saying you can't have a solution if you don't have a problem. So, we went out looking for solutions to ways that the world might end tomorrow, and lo and behold 4, we found them. Which leads me to a videotape of a President Bush press conference from a couple of weeks ago. Can we run that, Andrew?
President George W. Bush: Whatever it costs to defend our security, and whatever it costs to defend our freedom, we must pay it.
SP: I agree with the president. He wants two trillion dollars to protect us from terrorists next year, a two-trillion-dollar federal budget, which will land us back into deficit 5 spending real fast. But terrorists aren't the only threat we face. There are really serious calamities 6 staring us in the eye that we're in the same kind of denial about that we were about terrorism, and what could've happened on September 11.
I would propose, therefore, that if we took 10 billion dollars from that 2.13 trillion dollar budget -- which is two one hundredths of that budget -- and we doled 7 out a billion dollars to each one of these problems I'm going to talk to you about, the vast majority could be solved, and the rest we could deal with. So, I hope you find this both fascinating -- I'm fascinated by this kind of stuff, I gotta admit -- to me these are Richard's cockroaches 8.
But I also hope, because I think the people in this room can literally 9 change the world, I hope you take some of this stuff away with you, and when you have an opportunity to be influential 10, that you try to get some heavy-duty money spent on some of these ideas.
So let's start. Number 10: we lose the will to survive. We live in an incredible age of modern medicine. We are all much healthier than we were 20 years ago. People around the world are getting better medicine -- but mentally, we're falling apart. The World Health Organization now estimates that one out of five people on the planet is clinically depressed 11. And the World Health Organization also says that depression is the biggest epidemic 12 that humankind has ever faced.
Soon, genetic 13 breakthroughs and even better medicine are going to allow us to think of 100 as a normal lifespan. A female child born tomorrow, on average -- median -- will live to age 83. Our life longevity 14 is going up almost a year for every year that passes. Now the problem with all of this, getting older, is that people over 65 are the most likely people to commit suicide.
So, what are the solutions? We don't really have mental health insurance in this country, and it's -- (Applause) -- it's really a crime. Something like 98 percent of all people with depression, and I mean really severe depression -- I have a friend with stunningly 15 severe depression -- this is a curable disease, with present medicine and present technology. But it is often a combination of talk therapy and pills. Pills alone don't do it, especially in clinically depressed people. You ought to be able to go to a psychiatrist 16 or a psychologist, and put down your 10-dollar copay, and get treated, just like you do when you got a cut on your arm. It's ridiculous.
Secondly 17, drug companies are not going to develop really sophisticated psychoactive drugs. We know that most mental illnesses have a biological component 18 that can be dealt with. And we know just an amazing amount more about the brain now than we did 10 years ago. We need a pump-push from the federal government, through NIH and National Science -- NSF -- and places like that to start helping 19 the drug companies develop some advanced psychoactive drugs.
Moving on. Number nine -- don't laugh -- aliens invade Earth. Ten years ago, you couldn't have found an astronomer 20 -- well, very few astronomers 21 -- in the world who would've told you that there are any planets anywhere outside our solar system. 1995, we found three. The count now is up to 80 -- we're finding about two or three a month. All of the ones we've found, by the way, are in this little, teeny, tiny corner where we live, in the Milky 22 Way. There must be millions of planets in the Milky Way, and as Carl Sagan insisted for many years, and was laughed at for it, there must be billions and billions in the universe. In a few years, NASA is going to launch four or five telescopes out to Jupiter, where there's less dust, and start looking for Earth-like planets, which we cannot see with present technology, nor detect. It's becoming obvious that the chance that life does not exist elsewhere in the universe, and probably fairly close to us, is a fairly remote idea. And the chance that some of it isn't more intelligent than ours is also a remote idea.
Remember, we've only been an advanced civilization -- an industrial civilization, if you would -- for 200 years. Although every time I go to Pompeii, I'm amazed that they had the equivalent of a McDonald's on every street corner, too. So, I don't know how much civilization really has progressed since AD 79, but there's a great likelihood. I really believe this, and I don't believe in aliens, and I don't believe there are any aliens on the Earth or anything like that. But there's a likelihood that we will confront a civilization that is more intelligent than our own.
Now, what will happen? What if they come to, you know, suck up our oceans for the hydrogen? And swat us away like flies, the way we swat away flies when we go into the rainforest and start logging it. We can look at our own history. The late physicist 23 Gerard O'Neill said, "Advanced Western civilization has had a destructive effect on all primitive 24 civilizations it has come in contact with, even in those cases where every attempt was made to protect and guard the primitive civilization." If the aliens come visiting, we're the primitive civilization.
So, what are the solutions to this? (Laughter) Thank God you can all read! It may seem ridiculous, but we have a really lousy history of anticipating things like this and actually being prepared for them. How much energy and money does it take to actually have a plan to negotiate with an advanced species?
Secondly -- and you're going to hear more from me about this -- we have to become an outward-looking, space-faring nation. We have got to develop the idea that the Earth doesn't last forever, our sun doesn't last forever. If we want humanity to last forever, we have to colonize 25 the Milky Way. And that is not something that is beyond comprehension at this point. (Applause) It'll also help us a lot, if we meet an advanced civilization along the way, if we're trying to be an advanced civilization. Number eight --
(Voice: Steve, that's what I'm doing after TED.) (Laughter) (Applause)
SP: You've got it! You've got the job.
Number eight: the ecosystem 26 collapses 28. Last July, in Science, the journal Science, 19 oceanographers published a very, very unusual article. It wasn't really a research report; it was a screed 29. They said, we've been looking at the oceans for a long time now, and we want to tell you they're not in trouble, they're near collapse 27. Many other ecosystems 30 on Earth are in real, real danger. We're living in a time of mass extinctions that exceeds the fossil record by a factor of 10,000. We have lost 25 percent of the unique species in Hawaii in the last 20 years. California is expected to lose 25 percent of its species in the next 40 years. Somewhere in the Amazon forest is the marginal tree. You cut down that tree, the rain forest collapses as an ecosystem. There's really a tree like that out there. That's really what it comes to. And when that ecosystem collapses, it could take a major ecosystem with it, like our atmosphere. So, what do we do about this? What are the solutions?
There is some modeling of ecosystems going on now. The problem with ecosystems is that we understand them so poorly, that we don't know they're really in trouble until it's almost too late. We need to know earlier that they're getting in trouble, and we need to be able to pump possible solutions into models. And with the kind of computing 31 power we have now, there is, as I say, some of this going on, but it needs money. National Science Foundation needs to say -- you know, almost all the money that's spent on science in this country comes from the federal government, one way or another. And they get to prioritize, you know? There are people at the National Science Foundation who get to say, this is the most important thing. This is one of the things they ought to be thinking more about.
Secondly, we need to create huge biodiversity reserves on the planet, and start moving them around. There's been an experiment for the last four or five years on the Georges Bank, or the Grand Banks off of Newfoundland. It's a no-take fishing zone. They can't fish there for a radius 32 of 200 miles. And an amazing thing has happened: almost all the fish have come back, and they're reproducing like crazy. We're going to have to start doing this around the globe. We're going to have to have no-take zones. We're going to have to say, no more logging in the Amazon for 20 years. Let it recover, before we start logging again. (Applause)
Number seven: particle accelerator mishap 33. You all remember Ted Kaczynski, the Unabomber? One of the things he raved 34 about was that a particle accelerator experiment could go haywire and set off a chain reaction that would destroy the world. A lot of very sober-minded physicists 35, believe it or not, have had exactly the same thought. This spring -- there's a collider at Brookhaven, on Long Island -- this spring, it's going to have an experiment in which it creates black holes. They are expecting to create little, tiny black holes. They expect them to evaporate. (Laughter) I hope they're right. (Laughter)
Other collider experiments -- there's one that's going to take place next summer at CERN -- have the possibility of creating something called strangelets, which are kind of like antimatter. Whenever they hit other matter, they destroy it and obliterate 36 it. Most physicists say that the accelerators we have now are not really powerful enough to create black holes and strangelets that we need to worry about, and they're probably right. But, all around the world, in Japan, in Canada, there's talk about this, of reviving this in the United States. We shut one down that was going to be big. But there's talk of building very big accelerators. What can we do about this? What are the solutions?
We've got the fox watching the henhouse here. We need to -- we need the advice of particle physicists to talk about particle physics and what should be done in particle physics, but we need some outside thinking and watchdogging of what's going on with these experiments.
Secondly, we have a natural laboratory surrounding the Earth. We have an electromagnetic field around the Earth, and it's constantly bombarded by high-energy particles, like protons. And in my opinion, we don't spend enough time looking at that natural laboratory and figuring out first what's safe to do on Earth.
Number six: biotech disaster. It's one of my favorite ones, because we've done several stories on Bt corn. Bt corn is a corn that creates its own pesticide 38 to kill a corn borer. You may of heard of it -- heard it called StarLink, especially when all those taco shells were taken out of the supermarkets about a year and a half ago. This stuff was supposed to only be feed for animals in the United States, and it got into the human food supply, and somebody should've figured out that it would get in the human food supply very easily. But the thing that's alarming is a couple of months ago, in Mexico, where Bt corn and all genetically 39 altered corn is totally illegal, they found Bt corn genes 40 in wild corn plants. Now, corn originated, we think, in Mexico. This is the genetic biodiversity storehouse of corn. This brings back a skepticism that has gone away recently, that superweeds and superpests could spread around the world, from biotechnology, that literally could destroy the world's food supply in very short order.
So, what do we do about that? We treat biotechnology with the same scrutiny 41 we apply to nuclear power plants. It's that simple. This is an amazingly unregulated field. When the StarLink disaster happened, there was a battle between the EPA and the FDA over who really had authority, and over what parts of this, and they didn't get it straightened out for months. That's kind of crazy.
Number five, one of my favorites: reversal of the Earth's magnetic field. Believe it or not, this happens every few hundred thousand years, and has happened many times in our history. North Pole goes to the South, South Pole goes to the North, and vice 37 versa. But what happens, as this occurs, is that we lose our magnetic field around the Earth over the period of about 100 years, and that means that all these cosmic rays and particles that are to come streaming at us from the sun, that this field protects us from, are -- well, basically, we're gonna fry. (Laughter)
(Voice: Steve, I have some additional hats downstairs.)
SP: So, what can we do about this? Oh, by the way, we're overdue 42. It's been 780,000 years since this happened. So, it should have happened about 480,000 years ago. Oh, and here's one other thing. Scientists think now our magnetic field may be diminished by about five percent. So, maybe we're in the throes of it. One of the problems of trying to figure out how healthy the Earth is, is that we have -- you know, we don't have good weather data from 60 years ago, much less data on things like the ozone 43 layer.
So, there's a fairly simple solution to this. There's going to be a lot of cheap rocketry that's going to come online in about six or seven years that gets us into the low atmosphere very cheaply. You know, we can make ozone from car tailpipes. It's not hard: it's just three oxygen atoms. If you brought the entire ozone layer down to the surface of the Earth, it would be the thickness of two pennies, at 14 pounds per square inch. You don't need that much up there. We need to learn how to repair and replenish 44 the Earth's ozone layer. (Applause)
Number four: giant solar flares 46. Solar flares are enormous magnetic outbursts from the Sun that bombard the Earth with high-speed subatomic particles. So far, our atmosphere has done, and our magnetic field has done pretty well protecting us from this. Occasionally, we get a flare 45 from the Sun that causes havoc 47 with communications and so forth 48, and electricity. But the alarming thing is that astronomers recently have been studying stars that are similar to our Sun, and they've found that a number of them, when they're about the age of our Sun, brighten by a factor of as much as 20. Doesn't last for very long. And they think these are super-flares, millions of times more powerful than any flares we've had from our Sun so far.
Obviously, we don't want one of those. (Laughter) There's a flip 49 side to it. In studying stars like our Sun, we've found that they go through periods of diminishment, when their total amount of energy that's expelled from them goes down by maybe one percent. One percent doesn't sound like a lot, but it would cause one hell of an ice age here. So, what can we do about this?
(Laughter) Start terraforming Mars. This is one of my favorite subjects. I wrote a story about this in Life magazine in 1993. This is rocket science, but it's not hard rocket science. Everything that we need to make an atmosphere on Mars, and to make a livable planet on Mars, is probably there. And you just, literally, have to send little nuclear factories up there that gobble up the iron oxide 50 on the surface of Mars and spit out the oxygen. The problem is it takes 300 years to terraform Mars, minimum. Really more like 500 years to do it right. There's no reason why we shouldn't start now. (Laughter)
Number three -- isn't this stuff cool? (Laughter) A new global epidemic. People have been at war with germs ever since there have been people, and from time to time, the germs sure get the upper hand. In 1918, we had a flu epidemic in the United States that killed 20 million people. That was back when the population was around 100 million people. The bubonic plague in Europe, in the Middle Ages, killed one out of four Europeans. AIDS is coming back. Ebola seems to be rearing its head with much too much frequency, and old diseases like cholera 51 are becoming resistant 52 to antibiotics 54. We've all learned what -- the kind of panic that can occur when an old disease rears its head, like anthrax.
The worst possibility is that a very simple germ, like staph, for which we have one antibiotic 53 that still works, mutates. And we know staph can do amazing things. A staph cell can be next to a muscle cell in your body and borrow genes from it when antibiotics come, and change and mutate. The danger is that some germ like staph will be -- will mutate into something that's really virulent 55, very contagious 56, and will sweep through populations before we can do anything about it. That's happened before. About 12,000 years ago, there was a massive wave of mammal extinctions in the Americas, and that is thought to have been a virulent disease. So, what can we do about it?
It is nuts. We give antibiotics -- (Applause) -- every cow, every lamb, every chicken, they get antibiotics every day, all. You know, you go to a restaurant, you eat fish, I got news for you, it's all farmed. You know, you gotta ask when you go to a restaurant if it's a wild fish, cause they're not going to tell you. We're giving away the code. This is like being at war and giving somebody your secret code. We're telling the germs out there how to fight us. We gotta fix that. We gotta outlaw 57 that right away.
Secondly, our public health system, as we saw with anthrax, is a real disaster. We have a real, major outbreak of disease in the United States, we are not prepared to cope with it. Now, there is money in the federal budget, next year, to build up the public health service. But I don't think to any extent that it really needs to be done.
Number two -- my favorite -- we meet a rogue 58 black hole. You know, 10 years ago, or 15 years ago, really, you walk into an astronomy convention, and you say, "You know, there's probably a black hole at the center of every galaxy," and they're going to hoot 59 you off the stage. And now, if you went into one of those conventions and you said, "Well, I don't think black holes are out there," they'd hoot you off the stage. Our comprehension of the way the universe works is really -- has just gained unbelievably in recent years.
We think that there are about 10 million dead stars in the Milky Way alone, our galaxy. And these stars have compressed down to maybe something like 12, 15 miles wide, and they are black holes. And they are gobbling up everything around them, including light, which is why we can't see them. Most of them should be in orbit around something. But galaxies 60 are very violent places, and things can be spun 61 out of orbit. And also, space is incredibly vast. So even if you flung a million of these things out of orbit, the chances that one would actually hit us is fairly remote. But it only has to get close, about a billion miles away, one of these things. About a billion miles away, here's what happens to Earth's orbit: it becomes elliptical instead of circular. And for three months out of the year, the surface temperatures go up to 150 to 180. For three months out of the year, they go to 50 below zero. That won't work too well. What can we do about this? And this is my scariest. (Laughter) I don't have a good answer for this one. Again, we gotta think about being a colonizing 62 race.
And finally, number one: biggest danger to life as we know it, I think, a really big asteroid 63 heads for Earth. The important thing to remember here -- this is not a question of if, this is a question of when, and how big. In 1908, just a 200-foot piece of a comet exploded over Siberia and flattened 64 forests for maybe 100 miles. It had the effect of about 1,000 Hiroshima bombs. Astronomers estimate that little asteroids 65 like that come about every hundred years. In 1989, a large asteroid passed 400,000 miles away from Earth.
Nothing to worry about, right? It passed directly through Earth's orbit. We were in that that spot six hours earlier. A small asteroid, say a half mile wide, would touch off firestorms followed by severe global cooling from the debris 66 kicked up -- Carl Sagan's nuclear winter thing. An asteroid five miles wide causes major extinctions. We think the one that got the dinosaurs 67 was about five miles wide. Where are they? There's something called the Kuiper belt, which -- some people think Pluto 68's not a planet, that's where Pluto is, it's in the Kuiper belt. There's also something a little farther out, called the Oort cloud. There are about 100,000 balls of ice and rock -- comets, really -- out there, that are 50 miles in diameter or more, and they regularly take a little spin, in towards the Sun and pass reasonably close to us. Of more concern, I think, is the asteroids that exist between Mars and Jupiter. The folks at the Sloan Digital Sky Survey told us last fall -- they're making the first map of the universe, three-dimensional map of the universe -- that there are probably 700,000 asteroids between Mars and Jupiter that are a half a mile big or bigger. So you say, yeah, well, what are really the chances of this happening? Andrew, can you put that chart up?
This is a chart that Dr. Clark Chapman at the Southwest Research Institute presented to Congress a few years ago. You'll notice that the chance of an asteroid-slash-comet impact killing 69 you is about one in 20,000, according to the work they've done. Now look at the one right below that. Passenger aircraft crash, one in 20,000. We spend an awful lot of money trying to be sure that we don't die in airplane accidents, and we're not spending hardly anything on this. And yet, this is completely preventable. We finally have, just in the last year, the technology to stop this cold. Could we have the solutions?
NASA's spending three million dollars a year, three million bucks 70 -- that is like pocket change -- to search for asteroids. Because we can actually figure out every asteroid that's out there, and if it might hit Earth, and when it might hit Earth. And they're trying to do that. But it's going to take them 10 years, at spending three million dollars a year, and even then, they claim they'll only have about 80 percent of them catalogued. Comets are a tougher act. We don't really have the technology to predict comet trajectories 71, or when one with our name on it might arrive. But we would have lots of time, if we see it coming. We really need a dedicated 72 observatory 73. You'll notice that a lot of comets are named after people you never heard of, amateur astronomers? That's because nobody's looking for them, except amateurs. We need a dedicated observatory that looks for comets.
Part two of the solutions: we need to figure out how to blow up an asteroid, or alter its trajectory 74. Now, a year ago, we did an amazing thing. We sent a probe out to this asteroid belt, called NEAR, Near Earth Asteroid Rendezvous 75. And these guys orbited a 30 -- or no, about a 22-mile long asteroid called Eros. And then, of course, you know, they pulled one of those sneaky NASA things, where they had extra batteries and extra gas aboard and everything, and then, at the last minute, they landed. When the mission was over, they actually landed on the thing. We have landed a rocket ship on an asteroid. It's not a big deal. Now, the trouble with just sending a bomb out for this thing is that you don't have anything to push against in space, because there's no air. A nuclear explosion is just as hot, but we don't really have anything big enough to melt a 22-mile long asteroid, or vaporize it, would be more like it.
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But we can learn to land on these asteroids that have our name on them and put something like a small ion propulsion motor on it, which would gently, slowly, after a period of time, push it into a different trajectory, which, if we've done our math right, would keep it from hitting Earth. This is just a matter of finding 'em, going there, and doing something about it. I know your head is spinning from all this stuff. Yikes! So many big threats!
The thing, I think, to remember, is September 11. We don't want to get caught flat-footed again. We know about this stuff. Science has the power to predict the future in many cases now. Knowledge is power. The worst thing we can do is say, jeez, I got enough to worry about without worrying about an asteroid. (Laughter) That's a mistake that could literally cost us our future. Thank you.

n.星系;银河系;一群(杰出或著名的人物)
  • The earth is one of the planets in the Galaxy.地球是银河系中的星球之一。
  • The company has a galaxy of talent.该公司拥有一批优秀的人才。
adv.不可避免地;必然发生地
  • In the way you go on,you are inevitably coming apart.照你们这样下去,毫无疑问是会散伙的。
  • Technological changes will inevitably lead to unemployment.技术变革必然会导致失业。
vt.翻晒,撒,撒开
  • The invaders gut ted the village.侵略者把村中财物洗劫一空。
  • She often teds the corn when it's sunny.天好的时候她就翻晒玉米。
v.看,注视,看到
  • The industry of these little ants is wonderful to behold.这些小蚂蚁辛勤劳动的样子看上去真令人惊叹。
  • The sunrise at the seaside was quite a sight to behold.海滨日出真是个奇景。
n.亏空,亏损;赤字,逆差
  • The directors have reported a deficit of 2.5 million dollars.董事们报告赤字为250万美元。
  • We have a great deficit this year.我们今年有很大亏损。
n.灾祸,灾难( calamity的名词复数 );不幸之事
  • They will only triumph by persevering in their struggle against natural calamities. 他们只有坚持与自然灾害搏斗,才能取得胜利。 来自《现代汉英综合大词典》
  • One moment's false security can bring a century of calamities. 图一时之苟安,贻百年之大患。 来自《现代汉英综合大词典》
救济物( dole的过去式和过去分词 ); 失业救济金
  • The food was doled out to the poor. 食品分发给了穷人。
  • Sisco briskly doled out the United States positions on the key issues. 西斯科轻快地把美国在重大问题上的立场放了出去。
n.蟑螂( cockroach的名词复数 )
  • At night, the cockroaches filled the house with their rustlings. 夜里,屋里尽是蟑螂窸窸瑟瑟的声音。 来自辞典例句
  • It loves cockroaches, and can keep a house clear of these hated insects. 它们好食蟑螂,可以使住宅免除这些讨厌昆虫的骚扰。 来自百科语句
adv.照字面意义,逐字地;确实
  • He translated the passage literally.他逐字逐句地翻译这段文字。
  • Sometimes she would not sit down till she was literally faint.有时候,她不走到真正要昏厥了,决不肯坐下来。
adj.有影响的,有权势的
  • He always tries to get in with the most influential people.他总是试图巴结最有影响的人物。
  • He is a very influential man in the government.他在政府中是个很有影响的人物。
adj.沮丧的,抑郁的,不景气的,萧条的
  • When he was depressed,he felt utterly divorced from reality.他心情沮丧时就感到完全脱离了现实。
  • His mother was depressed by the sad news.这个坏消息使他的母亲意志消沉。
n.流行病;盛行;adj.流行性的,流传极广的
  • That kind of epidemic disease has long been stamped out.那种传染病早已绝迹。
  • The authorities tried to localise the epidemic.当局试图把流行病限制在局部范围。
adj.遗传的,遗传学的
  • It's very difficult to treat genetic diseases.遗传性疾病治疗起来很困难。
  • Each daughter cell can receive a full complement of the genetic information.每个子细胞可以收到遗传信息的一个完全补偿物。
n.长命;长寿
  • Good habits promote longevity.良好的习惯能增长寿命。
  • Human longevity runs in families.人类的长寿具有家族遗传性。
ad.令人目瞪口呆地;惊人地
  • The cooks, seamstresses and other small investors are stunningly vulnerable to reversals. 那些厨师、裁缝及其他的小投资者非常容易受到股市逆转的影响。
  • The production cost of this huge passenger liner is stunningly high. 这艘船城造价之高令人惊叹。
n.精神病专家;精神病医师
  • He went to a psychiatrist about his compulsive gambling.他去看精神科医生治疗不能自拔的赌瘾。
  • The psychiatrist corrected him gently.精神病医师彬彬有礼地纠正他。
adv.第二,其次
  • Secondly,use your own head and present your point of view.第二,动脑筋提出自己的见解。
  • Secondly it is necessary to define the applied load.其次,需要确定所作用的载荷。
n.组成部分,成分,元件;adj.组成的,合成的
  • Each component is carefully checked before assembly.每个零件在装配前都经过仔细检查。
  • Blade and handle are the component parts of a knife.刀身和刀柄是一把刀的组成部分。
n.食物的一份&adj.帮助人的,辅助的
  • The poor children regularly pony up for a second helping of my hamburger. 那些可怜的孩子们总是要求我把我的汉堡包再给他们一份。
  • By doing this, they may at times be helping to restore competition. 这样一来, 他在某些时候,有助于竞争的加强。
n.天文学家
  • A new star attracted the notice of the astronomer.新发现的一颗星引起了那位天文学家的注意。
  • He is reputed to have been a good astronomer.他以一个优秀的天文学者闻名于世。
n.天文学者,天文学家( astronomer的名词复数 )
  • Astronomers can accurately foretell the date,time,and length of future eclipses. 天文学家能精确地预告未来日食月食的日期、时刻和时长。 来自《简明英汉词典》
  • Astronomers used to ask why only Saturn has rings. 天文学家们过去一直感到奇怪,为什么只有土星有光环。 来自《简明英汉词典》
adj.牛奶的,多奶的;乳白色的
  • Alexander always has milky coffee at lunchtime.亚历山大总是在午餐时喝掺奶的咖啡。
  • I like a hot milky drink at bedtime.我喜欢睡前喝杯热奶饮料。
n.物理学家,研究物理学的人
  • He is a physicist of the first rank.他是一流的物理学家。
  • The successful physicist never puts on airs.这位卓有成就的物理学家从不摆架子。
adj.原始的;简单的;n.原(始)人,原始事物
  • It is a primitive instinct to flee a place of danger.逃离危险的地方是一种原始本能。
  • His book describes the march of the civilization of a primitive society.他的著作描述了一个原始社会的开化过程。
v.建立殖民地,拓殖;定居,居于
  • Around 700 Arabs began to colonize East Africa.公元700年阿拉伯人开始把东非变为殖民地。
  • Japan used to colonize many countries in Asia.日本曾经殖民过许多亚洲国家。
n.生态系统
  • This destroyed the ecosystem of the island.这样破坏了岛上的生态系统。
  • We all have an interest in maintaining the integrity of the ecosystem.维持生态系统的完整是我们共同的利益。
vi.累倒;昏倒;倒塌;塌陷
  • The country's economy is on the verge of collapse.国家的经济已到了崩溃的边缘。
  • The engineer made a complete diagnosis of the bridge's collapse.工程师对桥的倒塌做了一次彻底的调查分析。
折叠( collapse的第三人称单数 ); 倒塌; 崩溃; (尤指工作劳累后)坐下
  • This bridge table collapses. 这张桥牌桌子能折叠。
  • Once Russia collapses, the last chance to stop Hitler will be gone. 一旦俄国垮台,抑止希特勒的最后机会就没有了。
n.长篇大论
  • The screed tired the audience.那篇冗长的演说使听众厌烦了。
  • The pro-whaling screed was approved by a much thinner margin:33 votes to 32.关于捕鲸的冗长决议是以33票对32票的微弱差数通过的。
n.生态系统( ecosystem的名词复数 )
  • There are highly sensitive and delicately balanced ecosystems in the forest. 森林里有高度敏感、灵敏平衡的各种生态系统。 来自《简明英汉词典》
  • Madagascar's ecosystems range from rainforest to semi-desert. 马达加斯加生态系统类型多样,从雨林到半荒漠等不一而足。 来自辞典例句
n.计算
  • to work in computing 从事信息处理
  • Back in the dark ages of computing, in about 1980, they started a software company. 早在计算机尚未普及的时代(约1980年),他们就创办了软件公司。
n.半径,半径范围;有效航程,范围,界限
  • He has visited every shop within a radius of two miles.周围两英里以内的店铺他都去过。
  • We are measuring the radius of the circle.我们正在测量圆的半径。
n.不幸的事,不幸;灾祸
  • I'm afraid your son had a slight mishap in the playground.不好了,你儿子在操场上出了点小意外。
  • We reached home without mishap.我们平安地回到了家。
v.胡言乱语( rave的过去式和过去分词 );愤怒地说;咆哮;痴心地说
  • Andrew raved all night in his fever. 安德鲁发烧时整夜地说胡话。 来自《简明英汉词典》
  • They raved about her beauty. 他们过分称赞她的美。 来自《现代英汉综合大词典》
物理学家( physicist的名词复数 )
  • For many particle physicists, however, it was a year of frustration. 对于许多粒子物理学家来说,这是受挫折的一年。 来自英汉非文学 - 科技
  • Physicists seek rules or patterns to provide a framework. 物理学家寻求用法则或图式来构成一个框架。
v.擦去,涂抹,去掉...痕迹,消失,除去
  • Whole villages were obliterated by fire.整座整座的村庄都被大火所吞噬。
  • There was time enough to obliterate memories of how things once were for him.时间足以抹去他对过去经历的记忆。
n.坏事;恶习;[pl.]台钳,老虎钳;adj.副的
  • He guarded himself against vice.他避免染上坏习惯。
  • They are sunk in the depth of vice.他们堕入了罪恶的深渊。
n.杀虫剂,农药
  • The pesticide was spread over the vegetable plot.菜田里撒上了农药。
  • This pesticide is diluted with water and applied directly to the fields.这种杀虫剂用水稀释后直接施用在田里。
adv.遗传上
  • All the bees in the colony are genetically related. 同一群体的蜜蜂都有亲缘关系。
  • Genetically modified foods have already arrived on American dinner tables. 经基因改造加工过的食物已端上了美国人的餐桌。 来自英汉非文学 - 生命科学 - 基因与食物
n.基因( gene的名词复数 )
  • You have good genes from your parents, so you should live a long time. 你从父母那儿获得优良的基因,所以能够活得很长。 来自《简明英汉词典》
  • Differences will help to reveal the functions of the genes. 它们间的差异将会帮助我们揭开基因多种功能。 来自英汉非文学 - 生命科学 - 生物技术的世纪
n.详细检查,仔细观察
  • His work looks all right,but it will not bear scrutiny.他的工作似乎很好,但是经不起仔细检查。
  • Few wives in their forties can weather such a scrutiny.很少年过四十的妻子经得起这么仔细的观察。
adj.过期的,到期未付的;早该有的,迟到的
  • The plane is overdue and has been delayed by the bad weather.飞机晚点了,被坏天气耽搁了。
  • The landlady is angry because the rent is overdue.女房东生气了,因为房租过期未付。
n.臭氧,新鲜空气
  • The ozone layer is a protective layer around the planet Earth.臭氧层是地球的保护层。
  • The capacity of ozone can adjust according of requirement.臭氧的产量可根据需要或调节。
vt.补充;(把…)装满;(再)填满
  • I always replenish my food supply before it is depleted.我总是在我的食物吃完之前加以补充。
  • We have to import an extra 4 million tons of wheat to replenish our reserves.我们不得不额外进口四百万吨小麦以补充我们的储备。
v.闪耀,闪烁;n.潮红;突发
  • The match gave a flare.火柴发出闪光。
  • You need not flare up merely because I mentioned your work.你大可不必因为我提到你的工作就动怒。
n.喇叭裤v.(使)闪耀( flare的第三人称单数 );(使)(船舷)外倾;(使)鼻孔张大;(使)(衣裙、酒杯等)呈喇叭形展开
  • The side of a ship flares from the keel to the deck. 船舷从龙骨向甲板外倾。 来自《简明英汉词典》
  • He's got a fiery temper and flares up at the slightest provocation. 他是火爆性子,一点就着。 来自《现代汉英综合大词典》
n.大破坏,浩劫,大混乱,大杂乱
  • The earthquake wreaked havoc on the city.地震对这个城市造成了大破坏。
  • This concentration of airborne firepower wrought havoc with the enemy forces.这次机载火力的集中攻击给敌军造成很大破坏。
adv.向前;向外,往外
  • The wind moved the trees gently back and forth.风吹得树轻轻地来回摇晃。
  • He gave forth a series of works in rapid succession.他很快连续发表了一系列的作品。
vt.快速翻动;轻抛;轻拍;n.轻抛;adj.轻浮的
  • I had a quick flip through the book and it looked very interesting.我很快翻阅了一下那本书,看来似乎很有趣。
  • Let's flip a coin to see who pays the bill.咱们来抛硬币决定谁付钱。
n.氧化物
  • Oxide is usually seen in our daily life.在我们的日常生活中氧化物很常见。
  • How can you get rid of this oxide coating?你们该怎样除去这些氧化皮?
n.霍乱
  • The cholera outbreak has been contained.霍乱的发生已被控制住了。
  • Cholera spread like wildfire through the camps.霍乱在营地里迅速传播。
adj.(to)抵抗的,有抵抗力的
  • Many pests are resistant to the insecticide.许多害虫对这种杀虫剂有抵抗力。
  • They imposed their government by force on the resistant population.他们以武力把自己的统治强加在持反抗态度的人民头上。
adj.抗菌的;n.抗生素
  • The doctor said that I should take some antibiotic.医生说我应该服些用抗生素。
  • Antibiotic can be used against infection.抗菌素可以用来防止感染。
n.(用作复数)抗生素;(用作单数)抗生物质的研究;抗生素,抗菌素( antibiotic的名词复数 )
  • the discovery of antibiotics in the 20th century 20世纪抗生素的发现
  • The doctor gave me a prescription for antibiotics. 医生给我开了抗生素。
adj.有毒的,有恶意的,充满敌意的
  • She is very virulent about her former employer.她对她过去的老板恨之入骨。
  • I stood up for her despite the virulent criticism.尽管她遭到恶毒的批评,我还是维护她。
adj.传染性的,有感染力的
  • It's a highly contagious infection.这种病极易传染。
  • He's got a contagious laugh.他的笑富有感染力。
n.歹徒,亡命之徒;vt.宣布…为不合法
  • The outlaw hid out in the hills for several months.逃犯在山里隐藏了几个月。
  • The outlaw has been caught.歹徒已被抓住了。
n.流氓;v.游手好闲
  • The little rogue had his grandpa's glasses on.这淘气鬼带上了他祖父的眼镜。
  • They defined him as a rogue.他们确定他为骗子。
n.鸟叫声,汽车的喇叭声; v.使汽车鸣喇叭
  • The sudden hoot of a whistle broke into my thoughts.突然响起的汽笛声打断了我的思路。
  • In a string of shrill hoot of the horn sound,he quickly ran to her.在一串尖声鸣叫的喇叭声中,他快速地跑向她。
星系( galaxy的名词复数 ); 银河系; 一群(杰出或著名的人物)
  • Quasars are the highly energetic cores of distant galaxies. 类星体是遥远星系的极为活跃的核心体。
  • We still don't know how many galaxies there are in the universe. 我们还不知道宇宙中有多少个星系。
v.纺,杜撰,急转身
  • His grandmother spun him a yarn at the fire.他奶奶在火炉边给他讲故事。
  • Her skilful fingers spun the wool out to a fine thread.她那灵巧的手指把羊毛纺成了细毛线。
v.开拓殖民地,移民于殖民地( colonize的现在分词 )
  • The art of colonizing is no exception to the rule. 殖民的芸术是� 有特例的。 来自互联网
  • A Lesson for Other Colonizing Nations. 其它殖民国家学习的教训。 来自互联网
n.小行星;海盘车(动物)
  • Astronomers have yet to witness an asteroid impact with another planet.天文学家还没有目击过小行星撞击其它行星。
  • It's very unlikely that an asteroid will crash into Earth but the danger exists.小行星撞地球的可能性很小,但这样的危险还是存在的。
[医](水)平扁的,弄平的
  • She flattened her nose and lips against the window. 她把鼻子和嘴唇紧贴着窗户。
  • I flattened myself against the wall to let them pass. 我身体紧靠着墙让他们通过。
n.小行星( asteroid的名词复数 );海盘车,海星
  • Asteroids,also known as "minor planets",are numerous in the outer space. 小行星,亦称为“小型行星”,在外太空中不计其数。
  • Most stars probably have their quota of planets, meteorids, comets, and asteroids. 多数恒星也许还拥有若干行星、流星、彗星和小行星。
n.瓦砾堆,废墟,碎片
  • After the bombing there was a lot of debris everywhere.轰炸之后到处瓦砾成堆。
  • Bacteria sticks to food debris in the teeth,causing decay.细菌附着在牙缝中的食物残渣上,导致蛀牙。
n.恐龙( dinosaur的名词复数 );守旧落伍的人,过时落后的东西
  • The brontosaurus was one of the largest of all dinosaurs. 雷龙是所有恐龙中最大的一种。 来自《简明英汉词典》
  • Dinosaurs have been extinct for millions of years. 恐龙绝种已有几百万年了。 来自《简明英汉词典》
n.冥王星
  • Pluto is the furthest planet from the sun.冥王星是离太阳最远的行星。
  • Pluto has an elliptic orbit.冥王星的轨道是椭圆形的。
n.巨额利润;突然赚大钱,发大财
  • Investors are set to make a killing from the sell-off.投资者准备清仓以便大赚一笔。
  • Last week my brother made a killing on Wall Street.上个周我兄弟在华尔街赚了一大笔。
n.雄鹿( buck的名词复数 );钱;(英国十九世纪初的)花花公子;(用于某些表达方式)责任v.(马等)猛然弓背跃起( buck的第三人称单数 );抵制;猛然震荡;马等尥起后蹄跳跃
  • They cost ten bucks. 这些值十元钱。
  • They are hunting for bucks. 他们正在猎雄兔。 来自《简明英汉词典》
n.弹道( trajectory的名词复数 );轨道;轨线;常角轨道
  • To answer this question, we need to plot trajectories of principal stresses. 为了回答这个问题,我们尚须画出主应力迹线图。 来自辞典例句
  • In the space program the theory is used to determine spaceship trajectories. 在空间计划中,这个理论用于确定飞船的轨道。 来自辞典例句
adj.一心一意的;献身的;热诚的
  • He dedicated his life to the cause of education.他献身于教育事业。
  • His whole energies are dedicated to improve the design.他的全部精力都放在改进这项设计上了。
n.天文台,气象台,瞭望台,观测台
  • Guy's house was close to the observatory.盖伊的房子离天文台很近。
  • Officials from Greenwich Observatory have the clock checked twice a day.格林威治天文台的职员们每天对大钟检查两次。
n.弹道,轨道
  • It is not difficult to sketch the subsequent trajectory.很容易描绘出它们最终的轨迹。
  • The path followed by a projectile is called its trajectory.抛物体所循的路径称为它的轨道。
n.约会,约会地点,汇合点;vi.汇合,集合;vt.使汇合,使在汇合地点相遇
  • She made the rendezvous with only minutes to spare.她还差几分钟时才来赴约。
  • I have a rendezvous with Peter at a restaurant on the harbour.我和彼得在海港的一个餐馆有个约会。
学英语单词
able whackets
access key organization
aerometric measurement
altispinax
ametryn
amidopyrine test
anion-exchange chromatography
antitubercular drug
automatic logistrip
black root of tobacco
body-packer
brinkwood
calostoma raveneliis
cardinal spider
charered ship
chia ling p'in
Chignecto Isthmus
Claudius' fossae
CMESA
dazzle lamp
dies non juridicus
drilling cutings
dynamic stability index
enithares sinica
ethylenediaminetetraacetate
external transmit clock
forbidden zone of cloud formation
fresh water arrival draft
fusariella formosana
gelidiella acerosa
gingival col
glueily
ground-statest
heliometers
high brightness slide projector
horsemarket
Höskuldsstadhir
in pup
instantaneous reaction
integral square error approximation
itinerant merchant
Khunzakhskiy Rayon
kristol
lebovitz
Lendl
liquid-solid quilibrium
m. triceps sur?
mealy bug
meta-theoretical analysis
mortgageless
Mrs. Humphrey Ward
multieffect evaporator
near-end operated terminal
network teletype
NIHF
nonsurety
nozzle block
off axis parabolic mirror
organocadmium
Oswe
overstien
parallel misalignment
Peacock Pt.
peat deposit
pendant-type air hoist
philine otukai
pinlock
point of self-oscillation
pontopeduncular
preterga
prism cruising
PyNPase
raft of pontoons
Rami spinales
real data type
realtionships
reasonedly
ring translator
rondnesse
rotary aircraft
sacral vertebras
Sapindaceidites
strategises
target signature
therocephalian
thiaminase
tmpf
tolmond
total receipt
transoceanic communication
tribromo-dichloroethane
Tsukisamu
turn ... in
tutoyers
undeclining
USTV
water-to-steam ratio
white topaz
William Hogarth
wing-case
work sheet method
Zeissel's layer