剑桥雅思阅读真题解析(推荐3篇)

剑桥雅思13Test4雅思阅读passage 3真题+解析相关阅读：剑桥雅思13Test4阅读passage3真题+翻译体载议论文主要内容本文对《幸福产业》一书及其作者哲学观点进行了点评结构第1段:积极心理学的内涵。

第2段:积极心理学的支持者的哲学理论缺陷。

第3段:《幸福产业》的作者提出的观点及该书的优点。

第4段: Bentham提出量化幸福的两种方法。

第5段:人的行为可以被塑造。

第6段:促进幸福不应当是政府的责任。

Questions 27-29Choose the correct letter, A, B, C or D.Write the correct letter in boxes 27-29 on your answer sheet.27 What is the reviewer’s attitude to advocates of positive psychology?A They are wrong to reject the ideas of Bentham.B They are over-influenced by their study of Bentham’s theories.C They have a fresh new approach to ideas on human happiness.D They are ignorant about the ideas they should be considering.28 The reviewer refers to the Greek philosopher Aristotle in order to suggest that happinessA may not be just pleasure and the absence of pain.B should not be the main goal of humans.C is not something that should be fought for.D is not just an abstract concept.29 According to Davies, Bentham’s suggestion for linking the price of goods to happiness was significant becauseA it was the first successful way of assessing happiness.B it established a connection between work and psychology.C it was the first successful example of psychological research.D it involved consideration of the rights of consumers.考题解析Questions27-29●题目类型:Multiple choice单项选择题是雅思阅读中难度相当大的一种题型。

剑桥雅思阅读真题答案：Question1—8：Y、N、Y、NG、Y、Y、N、YQuestion9—12：H、F、A、CPassage1整体分析体裁说明文题材语言学主题介绍两个语言学派的观点和态度段落概括第一段背景介绍：语言的普及性导致人们容易对其持有不同的看法第二段语言在社会各方面的影响第三段语言学派“规范主义”的观点第四段规范主义依赖于严格的语法规则及其目的第五段另一个语言学派“描写主义”的观点和态度第六段两个学派的现状及他们对彼此的误解雅思阅读重点词汇第一段objective adj.客观的debate n.争论，辩论linguistic adj.语言的，语言学的deteriorate v.衰退；恶化，变坏第二段criticise v.批评，批判social status社会地位exempt adj.被免除的，被豁免的identity n.身份；同一性第三段prescriptivism n.规范主义literature n.文学deviation n.背离be imposed on被强加于……之上adherent n.追随者第四段principle n.原则chaos n.混乱reliance n.依赖avoid v.避免beneath prep.在……之下dispute n.争论accurately adv.准确地，精确地alternative n.供代替的选择第五段motivate v.激发variation n.变化，改变第六段opposition n.反对valid adj.有效的advocate n.提倡者，支持者logic n.逻辑analysis n.分析diversity n.多样性halt v.停止，阻止original adj.最初的；独创的legislation n.立法；法律extreme adj.极端的考题精解Questions 1-8题型：判断题YES/NO/NOT GIVEN解析：判断题一般都是有顺序的，确定了第一道题的原文定位后，可以向后查找其他题目的答案。

剑桥雅思8-第三套试题-阅读部分-PASSAGE 1-阅读真题原文部分:READING PASSAGE 1You should spend about 20 minutes on Questions 1-13 which are based on Reading Passage 1 below.Striking Back at Lightning With LasersSeldom is the weather more dramatic than when thunderstorms strike. Their electrical fury inflicts death or serious injury on around 500 people each year in the United States alone. As the clouds roll in, a leisurely round of golf can become a terrifying dice with death - out in the open, a lone golfer may be a lightning bolt's most inviting target. And there is damage to property too. Lightning damage costs American power companies more than $100 million a year.But researchers in the United States and Japan are planning to hit back. Already in laboratory trials they have tested strategies for neutralising the power of thunderstorms, and this winter they will brave real storms, equipped with an armoury of lasers that they will be pointing towards the heavens to discharge thunderclouds before lightning can strike.The idea of forcing storm clouds to discharge their lightning on command is not new. In the early 1960s, researchers tried firing rockets trailing wires into thunderclouds to set up an easy discharge path for the huge electric charges that these clouds generate. The technique survives to this day at a test site in Florida run by the University of Florida, with support from the Electrical Power Research Institute (EPRI), based in California. EPRI, which is funded by power companies, is looking at ways to protect the United States' power grid from lightning strikes. 'We can cause the lightning to strike where we want it to using rockets, ' says Ralph Bernstein, manager of lightning projects at EPRI. The rocket site is providing precise measurements of lightning voltages and allowing engineers to check how electrical equipment bears up.Bad behaviourBut while rockets are fine for research, they cannot provide the protection from lightning strikes that everyone is looking for. The rockets cost around $1, 200 each, can only be fired at a limited frequency and their failure rate is about 40 per cent. And even when they do trigger lightning, things still do not always go according to plan. 'Lightning is not perfectly well behaved, 'says Bernstein. 'Occasionally, it will take a branch and go someplace it wasn't supposed to go. ' And anyway, who would want to fire streams of rockets in a populated area? 'What goes up must come down, ' points out Jean-Claude Diels of the University of New Mexico. Diels is leading a project, which is backed by EPRI, to try to use lasers to discharge lightning safely - and safety is a basic requirement since no one wants to put themselves or their expensive equipment at risk. With around $500, 000 invested so far, a promising system is just emerging from the laboratory.The idea began some 20 years ago, when high-powered lasers were revealing their ability to extract electrons out of atoms and create ions. If a laser could generate a line of ionisation in the air all the way up to a storm cloud, this conducting path could be used to guide lightning to Earth, before the electric field becomes strong enough to break down the air in an uncontrollable surge. To stop the laser itself being struck, it would not be pointed straight at the clouds. Instead it would be directed at a mirror, and from there into the sky. The mirror would be protected by placing lightning conductors close by. Ideally, the cloud-zapper (gun)would be cheap enough to be installed around all key power installations, and portable enough to be taken to international sporting events to beam up at brewing storm clouds.A stumbling blockHowever, there is still a big stumbling block. The laser is no nifty portable: it's a monster that takes up a whole room. Diels is trying to cut down the size and says that a laser around the size of a small table is in the offing. He plans to test this more manageable system on live thunderclouds next summer.Bernstein says that Diels's system is attracting lots of interest from the power companies. But they have not yet come up with the $5 million that EPRI says will be needed to develop a commercial system, by making the lasers yet smaller and cheaper. 'I cannot say I have money yet, but I'm working on it, ' says Bernstein. He reckons that the forthcoming field tests will be the turning point - and he's hoping for good news. Bernstein predicts 'an avalanche of interest and support' if all goes well. He expects to see cloud-zappers eventually costing 100, 000 each.Other scientists could also benefit. With a lightning 'switch' at their fingertips, materials scientists could find out what happens when mighty currents meet matter. Diels also hopes to see the birth of 'interactive meteorology' - not just forecasting the weather but controlling it. 'If we could discharge clouds, we might affect the weather, ' he says.And perhaps, says Diels, we'll be able to confront some other meteorological menaces. 'We think we could prevent hail by inducing lightning, ' he says. Thunder, the shock wave that comes from a lightning flash, is thought to be the trigger for the torrential rain that is typical of storms. A laser thunder factory could shake the moisture out of clouds, perhaps preventing the formation of the giant hailstones that threaten crops. With luck, as the storm clouds gather this winter, laser-toting researchers could, for the first time, strike back.Questions 1-3Choose the correct letter, A, B, C or D.Write the correct letter in boxes 1-3 on your answer sheet.1 The main topic discussed in the text isA the damage caused to US golf courses and golf players by lightning strikes.B the effect of lightning on power supplies in the US and in Japan.C a variety of methods used in trying to control lightning strikes.D a laser technique used in trying to control lightning strikes.2 According to the text, every year lightningA does considerable damage to buildings during thunderstorms.B kills or injures mainly golfers in the United States.C kills or injures around 500 people throughout the world.D damages more than 100 American power companies.3 Researchers at the University of Florida and at the University of New MexicoA receive funds from the same source.B are using the same techniques.C are employed by commercial companies.D are in opposition to each other.Questions 4-6Complete the sentences below.Choose NO MORE THAN TWO WORDS from the passage for each answer.Write your answers in boxes 4-6 on your answer sheet.4 EPRI receives financial support from………………………….5 The advantage of the technique being developed by Diels is that it can be used……………….6 The main difficulty associated with using the laser equipment is related to its……………….Questions 7-10Complete the summary using the list of words, A-I, below.Write the correct letter, A-I, in boxes 7-10 on your answer sheet.In this method, a laser is used to create a line of ionisation by removing electrons from 7 …………………………. This laser is then directed at 8 …………………………in order to control electrical charges, a method which is less dangerous than using 9 …………………………. As a protection for the lasers, the beams are aimed firstly at 10………………………….A cloud-zappersB atomsC storm cloudsD mirrorsE techniqueF ionsG rockets H conductors I thunderQuestions 11-13Do the following statements agree with the information given in Reading Passage 1?In boxes 11-13 on your answer sheet writeYES if the statement agrees with the claims of the writerNO if the statement contradicts the claims of the writerNOT GIVEN if it is impossible to say what the writer thinks about this11 Power companies have given Diels enough money to develop his laser.12 Obtaining money to improve the lasers will depend on tests in real storms.13 Weather forecasters are intensely interested in Diels's system.READING PASSAGE 1篇章结构体裁说明文主题用激光回击闪电结构第1段：闪电带来的危害第2段：科研人员正在研究回击闪电的方法第3段：先前的闪电回击术介绍第4段：火箭回击术的缺陷第5段：更安全的激光回击术第6段：激光回击术的技术原理第7段：激光回击术的缺陷第8段：通过实地实验改进激光回击术第9段：激光回击术对其他学科也有益处第10段：激光回击术的其他用途解题地图难度系数：★★★解题顺序：按题目顺序解答即可友情提示：烤鸭们注意：本文中的SUMMARY题目顺序有改变，解题要小心；MULTIPLE CHOICE的第三题是个亮点，爱浮想联翩的烤鸭们可能会糊掉。

剑桥雅思阅读9(test1)原文答案解析雅思阅读部分的真题资料，同学们需要进行一些细致的总结，比如说解析其实就是很重要的内容，接下来就是店铺给同学们带来的关于剑桥雅思阅读9原文解析(test1)的内容，一起来详细的分析一下吧，希望对你们的备考有所帮助。

剑桥雅思阅读9原文(test1)READING PASSAGE 1You should spend about 20 minutes on Questions 1-13, which are based on Reading Passage 1 below.William Henry PerkinThe man who invented synthetic dyesWilliam Henry Perkin was born on March 12, 1838, in London, England. As a boy, Perkin’s curiosity prompted early intere sts in the arts, sciences, photography, and engineering. But it was a chance stumbling upon a run-down, yet functional, laboratory in his late grandfather’s home that solidified the young man’s enthusiasm for chemistry.As a student at the City of London School, Perkin became immersed in the study of chemistry. His talent and devotion to the subject were perceived by his teacher, Thomas Hall, who encouraged him to attend a series of lectures given by the eminent scientist Michael Faraday at the Royal Institution. Those speeches fired the young chemist’s enthusiasm further, and he later went on to attend the Royal College of Chemistry, which he succeeded in entering in 1853, at the age of 15.At the time of Perkin’s enrolment, the Royal College of Chemistry was headed by the noted German chemist August Wilhelm Hofmann. Perkin’s scientific gifts soon caught Hofmann’s attention and, within two years, he becameHofmann’s youngest assistant. Not long after that, Perkin made the scientific breakthrough that would bring him both fame and fortune.At the time, quinine was the only viable medical treatment for malaria. The drug is derived from the bark of the cinchona tree, native to South America, and by 1856 demand for the drug was surpassing the available supply. Thus, when Hofmann made some passing comments about the desirability of a synthetic substitute for quinine, it was unsurprising that his star pupil was moved to take up the challenge.During his vacation in 1856, Perkin spent his time in the laboratory on th e top floor of his family’s house. He was attempting to manufacture quinine from aniline, an inexpensive and readily available coal tar waste product. Despite his best efforts, however, he did not end up with quinine. Instead, he produced a mysterious dark sludge. Luckily, Perkin’s scientific training and nature prompted him to investigate the substance further. Incorporating potassium dichromate and alcohol into the aniline at various stages of the experimental process, he finally produced a deep purple solution. And, proving the truth of the famous scientist Louis Pasteur’s words ‘chance favours only the prepared mind’, Perkin saw the potential of his unexpected find.Historically, textile dyes were made from such natural sources as plants and animal excretions. Some of these, such as the glandular mucus of snails, were difficult to obtain and outrageously expensive. Indeed, the purple colour extracted from a snail was once so costly in society at the time only the rich could afford it. Further, natural dyes tended to be muddy in hue and fade quickly. It was against this backdrop that Perkin’sdiscovery was made.Perkin quickly grasped that his purple solution could be used to colour fabric, thus making it the world’s first synthetic dye. Realising the importance of this breakthrough, he lost no time in patenting it. But perhaps the most fascinating of all Perkin’s reactions to his find was his nearly instant recognition that the new dye had commercial possibilities.Perkin originally named his dye Tyrian Purple, but it later became commonly known as mauve (from the French for the plant used to make the colour violet). He asked advice of Scottish dye works owner Robert Pullar, who assured him that manufacturing the dye would be well worth it if the colour remained fast (i.e. would not fade) and the cost was relatively low. So, over the fierce objections of his mentor Hofmann, he left college to give birth to the modern chemical industry.With the help of his father and brother, Perkin set up a factory not far from London. Utilising the cheap and plentiful coal tar that was an almost unlimited byproduct of London’s gas street lighting, the dye works began producing the world’s first synthetically dyed material in 1857. The company received a commercial boost from the Empress Eugenie of France, when she decided the new colour flattered her. Very soon, mauve was the necessary shade for all the fashionable ladies in that country. Not to be outdone, England’s Queen Victoria also appeared in public wearing a mauve gown, thus making it all the rage in England as well. The dye was bold and fast, and the public clamoured for more. Perkin went back to the drawing board.Although Perkin’s fame was achieved and fortune assured by his first discovery, the chemist continued his research. Among other dyes he developed and introduced were aniline red (1859)and aniline black (1863) and, in the late 1860s, Perkin’s green. It is important to note that Perkin’s synthetic dye discoveries had outcomes far beyond the merely decorative. The dyes also became vital to medical research in many ways. For instance, they were used to stain previously invisible microbes and bacteria, allowing researchers to identify such bacilli as tuberculosis, cholera, and anthrax. Artificial dyes continue to play a crucial role today. And, in what would have been particularly pleasing to Perkin, their current use is in the search for a vaccine against malaria.Questions 1-7Do the following statements agree with the information given in Reading Passage 1?In boxes 1-7 on your answer sheet, writeTRUE if the statement agrees with the informationFALSE if the statement contradicts the informationNOT GIVEN if there is no information on this1 Michael Faraday was the first person to recognise Perkin’s ability as a student of chemistry.2 Michael Faraday suggested Perkin should enrol in the Royal College of Chemistry.3 Perkin employed August Wilhelm Hofmann as his assistant.4 Perkin was still young when he made the discovery that made him rich and famous.5 The trees from which quinine is derived grow only in South America.6 Perkin hoped to manufacture a drug from a coal tar waste product.7 Perkin was inspired by the discoveries of the famous scientist Louis Pasteur.Questions 8-13Answer the questions below.Choose NO MORE THAN TWO WORDS from the passage for each answer.Write your answers in boxes 8-13 on your answer sheet.8 Before Perkin’s discovery, with what group in society was the colour purple associated?9 What potential did Perkin immediately understand that his new dye had?10 What was the name finally used to refer to the first colour Perkin invented?11 What was the name of the person Perkin consulted before setting up his own dye works?12 In what country did Perkin’s newly invented colour first become fashionable?13 According to the passage, which disease is now being targeted by researchers using synthetic dyes?READING PASSAGE 2You should spend about 20 minutes on Questions 14-26, which are based on Reading Passage 2 on the following pages.Questions 14-17Reading Passage 2 has five paragraphs, A-E.Choose the correct heading for paragraphs B-E from the list of headings below.Write the correct number, i-vii, in boxes 14-17 on your answer sheet.List of Headingsi Seeking the transmission of radio signals from planetsii Appropriate responses to signals from other civilisations iii Vast distances to Earth’s closest neighboursiv Assumptions underlying the search for extra-terrestrial intelligencev Reasons for the search for extra-terrestrial intelligencevi Knowledge of extra-terrestrial life formsvii Likelihood of life on other planetsExample AnswerParagraph A v14 Paragraph B15 Paragraph C16 Paragraph D17 Paragraph EIS THERE ANYBODY OUT THERE?The Search for Extra-terrestrial IntelligenceThe question of whether we are alone in the Universe has haunted humanity for centuries, but we may now stand poised on the brink of the answer to that question, as we search for radio signals from other intelligent civilisations. This search, often known by the acronym SETI (search for extra-terrestrial intelligence), is a difficult one. Although groups around the world have been searching intermittently for three decades, it is only now that we have reached the level of technology where we can make a determined attempt to search all nearby stars for any sign of life.AThe primary reason for the search is basic curiosity hethe same curiosity about the natural world that drives all pure science. We want to know whether we are alone in the Universe. We want to know whether life evolves naturally if given the right conditions, or whether there is something very special about the Earth to have fostered the variety of life forms that, we seearound us on the planet. The simple detection of a radio signal will be sufficient to answer this most basic of all questions. In this sense, SETI is another cog in the machinery of pure science which is continually pushing out the horizon of our knowledge. However, there are other reasons for being interested in whether life exists elsewhere. For example, we have had civilisation on Earth for perhaps only a few thousand years, and the threats of nuclear war and pollution over the last few decades have told us that our survival may be tenuous. Will we last another two thousand years or will we wipe ourselves out? Since the lifetime of a planet like ours is several billion years, we can expect that, if other civilisations do survive in our galaxy, their ages will range from zero to several billion years. Thus any other civilisation that we hear from is likely to be far older, on average, than ourselves. The mere existence of such a civilisation will tell us that long-term survival is possible, and gives us some cause for optimism. It is even possible that the older civilisation may pass on the benefits of their experience in dealing with threats to survival such as nuclear war and global pollution, and other threats that we haven’t yet discovered.BIn discussing whether we are alone, most SETI scientists adopt two ground rules. First, UFOs (Unidentified Flying Objects) are generally ignored since most scientists don’t consider the evidence for them to be strong enough to bear serious consideration (although it is also important to keep an open mind in case any really convincing evidence emerges in the future). Second, we make a very conservative assumption that we are looking for a life form that is pretty well like us, since if it differs radically from us we may well not recognise it as a life form,quite apart from whether we are able to communicate with it. In other words, the life form we are looking for may well have two green heads and seven fingers, but it will nevertheless resemble us in that it should communicate with its fellows, be interested in the Universe, live on a planet orbiting a star like our Sun, and perhaps most restrictively, have a chemistry, like us, based on carbon and water.CEven when we make these assumptions, our understanding of other life forms is still severely limited. We do not even know, for example, how many stars have planets, and we certainly do not know how likely it is that life will arise naturally, given the right conditions. However, when we look at the 100 billion stars in our galaxy (the Milky Way), and 100 billion galaxies in the observable Universe, it seems inconceivable that at least one of these planets does not have a life form on it; in fact, the best educated guess we can make, using the little that we do know about the conditions for carbon-based life, leads us to estimate that perhaps one in 100,000 stars might have a life-bearing planet orbiting it. That means that our nearest neighbours are perhaps 100 light years away, which is almost next door in astronomical terms.DAn alien civilistation could choose many different ways of sending information across the galaxy, but many of these either require too much energy, or else are severely attenuated while traversing the vast distances across the galaxy. It turns out that, for a given amount of transmitted power, radio waves in the frequency range 1000 to 3000 MHz travel the greatest distance, and so all searches to date have concentrated on looking forradio waves in this frequency range. So far there have been a number of searches by various groups around the world, including Australian searches using the radio telescope at Parkes, New South Wales. Until now there have not been any detections from the few hundred stars which have been searched. The scale of the searches has been increased dramatically since 1992, when the US Congress voted NASA $10 million per year for ten years to conduct, a thorough search for extra-terrestrial life. Much of the money in this project is being spent on developing the special hardware needed to search many frequencies at once. The project has two parts. One part is a targeted search using the world’s largest radio telescopes, the American-operated telescope in Arecibo, Puerto Rico and the French telescope in Nancy in France. This part of the project is searching the nearest 1000 likely stars with high sensitivity for signals in the frequency rang 1000 to 3000 MHz. The other part of the project is an undirected search which is monitoring all of space with a lower sensitivity, using the smaller antennas of NASA’s Deep Space Network.EThere is considerable debate over how we should react if we detect a signal from an alien civilisation. Everybody agrees that we should not reply immediately. Quite apart from the impracticality of sending a reply over such large distances at short notice, it raises a host of ethical questions that would have to be addressed by the global community before any reply could be sent. Would the human race face the culture shock if faced with a superior and much older civilisation? Luckily, there is no urgency about this. The stars being searched are hundreds of light years away, so it takes hundreds of years for their signal toreach us, and a further few hundred years for our reply to reach them. It’s not important, then, if there’s a delay of a few years, or decades, while the human race debates the question of whether to reply, and perhaps carefully drafts a reply.Questions 18-20Answer the questions below.Choose NO MORE THAN THREE WORDS AND/OR A NUMBER from the passage for each answer.Write your answers in boxes 18-20 on your answer sheet.18 What is the life expectancy of Earth?19 What kind of signals from other intelligent civilisations are SETI scientists searching for?20 How many stars are the world’s most powerful radio telescopes searching?Questions 21-26Do the following statements agree with the views of the writer in Reading Passage 2?In boxes 21-26 on your answer sheet, writeYES if the statement agrees with the views of the writerNO if the statement contradicts the views of the writerNOT GIVEN if it is impossible to say what the writer thinks about this21 Alien civilisations may be able to help the human race to overcome serious problems.22 SETI scientists are trying to find a life form that resembles humans in many ways.23 The Americans and Australians have co-operated on joint research projects.24 So far SETI scientists have picked up radio signals from several stars.25 The NASA project attracted criticism from some members of Congress.26 If a signal from outer space is received, it will be important to respond promptly.READING PASSAGE 3You should spend about 20 minutes on Questions 27-40, which are based on Reading Passage 3 below.The history of the tortoiseIf you go back far enough, everything lived in the sea. At various points in evolutionary history, enterprising individuals within many different animal groups moved out onto the land, sometimes even to the most parched deserts, taking their own private seawater with them in blood and cellular fluids. In addition to the reptiles, birds, mammals and insects which we see all around us, other groups that have succeeded out of water include scorpions, snails, crustaceans such as woodlice and land crabs, millipedes and centipedes, spiders and various worms. And we mustn’t forget the pla nts, without whose prior invasion of the land none of the other migrations could have happened.Moving from water to land involved a major redesign of every aspect of life, including breathing and reproduction. Nevertheless, a good number of thorough going land animals later turned around, abandoned their hard-earned terrestrial re-tooling, and returned to the water again. Seals have only gone part way back. They show us what the intermediates might have been like, on the way to extreme cases such as whales and dugongs. Whales (including the small whales we call dolphins) and dugongs, with their close cousins the manatees, ceased to be land creatures altogether and reverted to the full marine habits of their remote ancestors. They don’t even come ashoreto breed. They do, however, still breathe air, having never developed anything equivalent to the gills of their earlier marine incarnation. Turtles went back to the sea a very long time ago and, like all vertebrate returnees to the water, they breathe air. However, they are, in one respect, less fully given back to the water than whales or dugongs, for turtles still lay their eggs on beaches.There is evidence that all modern turtles are descended from a terrestrial ancestor which lived before most of the dinosaurs. There are two key fossils called Proganochelys quenstedti and Plaeochersis talampayensis dating from early dinosaur times, which appear to be close to the ancestry of all modern turtles and tortoises. You might wonder how we can tell whether fossil animals lived on land or in water, especially if only fragments are found. Sometimes it’s obvious. Ichthyosaurs were reptilian contemporaries of the dinosaurs, with fins and streamlined bodies. The fossils look like dolphins and they surely lived like dolphins, in the water. With turtles it is a little less obvious. One way to tell is by measuring the bones of their forelimbs.Walter Joyce and Jacques Gauthier, at Yale University, obtained three measurements in these particular bones of 71 species of living turtles and tortoises. They used a kind of triangular graph paper to plot the three measurements against one another. All the land tortoise species formed a tight cluster of points in the upper part of the triangle; all the water turtles cluster in the lower part of the triangular graph. There was no overlap, except when they added some species that spend time both in water and on land. Sure enough, these amphibious species show up on the triangular graph approximately half way between the ‘wet cluster’ of sea turtles and the ‘dry cluster’of land tortoises. The next step was to determine where the fossils fell. The bones of P. quenstedti and P. talampayensis leave us in no doubt. Their points on the graph are right in the thick of the dry cluster. Both these fossils were dry-land tortoises. They come from the era before our turtles returned to the water.You might think, therefore, that modern land tortoises have probably stayed on land ever since those early terrestrial times, as most mammals did after a few of them went back to the sea. But apparently not. If you draw out the family three of all modern turtles and tortoises, nearly all the branches are aquatic. Today’s land tortoises constitute a single branch, deeply nested among branches consisting of aquatic turtles. This suggests that modern land tortoises have not stayed on land continuously since the time of P. quenstedti and P. talampayensis. Rather, their ancestors were among those who went back to the water, and they then reemerged back onto the land in (relatively) more recent times.Tortoises therefore represent a remarkable double return. In common with all mammals, reptiles and birds, their remote ancestors were marine fish and before that various more or less worm-like creatures stretching back, still in the sea, to the primeval bacteria. Later ancestors lived on land and stayed there for a very large number of generations. Later ancestors still evolved back into the water and became sea turtles. And finally they returned yet again to the land as tortoises, some of which now live in the driest of deserts.Questions 27-30Answer the questions below.Choose NO MORE THAN TWO WORDS from the passage for each answer.Write your answers in boxes 27-30 on your answer sheet.27 What had to transfer from sea to land before any animals could migrate?28 Which TWO processes are mentioned as those in which animals had to make big changes as they moved onto lands?29 Which physical feature, possessed by their ancestors, do whales lack?30 which animals might ichthyosaurs have resembled?Questions 31-33Do the following statements agree with the information given in Reading Passage 3?In boxes 31-33 on your answer sheet, writeTRUE if the statement agrees with the informationFALSE if the statement contradicts the informationNOT GIVEN if there is no information on this31 Turtles were among the first group of animals to migrate back to the sea.32 It is always difficult to determine where an animal lived when its fossilised remains are incomplete.33 The habitat of ichthyosaurs can be determined by the appearance of their fossilised remains.Questions 34-39Complete the flow-chart below.Choose NO MORE THAN TWO WORDS AND/OR A NUMBER from the passage for each answer.Write your answers in boxes 34-39 on your answer sheet.Method of determining where the ancestors of turtles and tortoises come fromStep 171 species of living turtles and tortoises were examined anda total of 34 ……………………. were taken from the bones of theirforelimbs.Step 2The data was recorded on a 35 ……………….. (necessary for comparing the information).Outcome: Land tortoises were represented by a dense 36 …………………………… of points towards the top.Sea turtles were grouped together in the bottom part.Step 3The same data was collected from some living 37 ………………. species and added to the other results.Outcome: The points for these species turned out to be positioned about 38 ……………… up the triangle between the land tortoises and the sea turtles.Step 4Bones of P. quenstedti and P. talampayensis were examined in a similar way and the results added.Outcome: The position of the points indicated that both these ancient creatures were 39…………..Question 40Choose the correct letter, A, B, C or D.Write the correct letter in box 40 on your answer sheet.According to the writer, the most significant thing about tortoises is thatA they are able to adapt to life in extremely dry environments.B their original life form was a kind of primeval bacteria.C they have so much in common with sea turtles.D they have made the transition from sea to land more than once.剑桥雅思阅读9原文参考译文(test1)PASSAGE 1参考译文：William Henry Perkin 合成染料的发明者Wiliam Henry Perkin于1838年3月12日出生于英国伦敦。

剑桥雅思阅读8原文翻译及答案(test3)店铺为大家整理收集了剑桥雅思阅读8真题解析：test3阅读原文解析，希望对各位考生的备考有所帮助,祝每位烤鸭考试顺利，都能取得好成绩!剑桥雅思阅读8原文(test3)READING PASSAGE 1You should spend about 20 minutes on Questions 1-13, which are based on Reading Passage 1 below.Striking Back at LightningWith LasersSeldom is the weather more dramatic than when thunderstorms strike. Their electrical fury inflicts death or serious injury on around 500 people each year in the United States alone. As the clouds roll in, a leisurely round of golf can become a terrifying dice with death — out in the open, a lone golfer may be a lightning bolt’s most inviting target. And there is damage to property too. Lightning damage costs American power companies more than $100 million a year.But researchers in the United States and Japan are planning to hit back. Already in laboratory trials they have tested strategies for neutralising the power of thunderstorms, and this winter they will brave real storms, equipped with an armoury of lasers that they will be pointing towards the heavens to discharge thunderclouds before lightning can strike.The idea of forcing storm clouds to discharge their lightning on command is not new. In the early 1960s, researchers tried firing rockets trailing wires into thunderclouds to set up an easy discharge path for the huge electric charges that these clouds generate. The technique survives to this day at a test site inFlorida run by the University of Florida, with support from the Electrical Power Research Institute (EPRI), based in California. EPRI, which is funded by power companies, is looking at ways to protect the United States’ power grid from lightning strikes. ‘We can cause the lightning to strike where we want it to usin g rockets,’ says Ralph Bernstein, manager of lightning projects at EPRI. The rocket site is providing precise measurements of lightning voltages and allowing engineers to check how electrical equipment bears up.Bad behaviourBut while rockets are fine for research, they cannot provide the protection from lightning strikes that everyone is looking for. The rockets cost around $1,200 each, can only be fired at a limited frequency and their failure rate is about 40 per cent. And even when they do trigger lightning, things still do not always go according to plan. ‘Lightning is not perfectly well behaved,’ says Bernstein. ‘Occasionally, it will take a branch and go someplace it wasn’t supposed to go.’And anyway, who would want to fire streams of rockets in a p opulated area? ‘What goes up must come down,’ points out Jean-Claude Diels of the University of New Mexico. Diels is leading a project, which is backed by EPRI, to try to use lasers to discharge lightning safely —and safety is a basic requirement since no one wants to put themselves or their expensive equipment at risk. With around $500,000 invested so far, a promising system is just emerging from the laboratory.The idea began some 20 years ago, when high-powered lasers were revealing their ability to extract electrons out of atoms and create ions. If a laser could generate a line of ionisation in the air all the way up to a storm cloud, thisconducting path could be used to guide lightning to Earth, before the electric field becomes strong enough to break down the air in an uncontrollable surge. T o stop the laser itself being struck, it would not be pointed straight at the clouds. Instead it would be directed at a mirror, and from there into the sky. The mirror would be protected by placing lightning conductors close by. Ideally, the cloud-zapper (gun) would be cheap enough to be installed around all key power installations, and portable enough to be taken to international sporting events to beam up at brewing storm clouds.A stumbling blockHowever, there is still a big stumbling block. The laser is no nifty portable: it’s a monster that takes up a whole room. Diels is trying to cut down the size and says that a laser around the size of a small table is in the offing. He plans to test this more manageable system on live thunderclouds next summer.Bernstein says that Diels’s system is attracting lots of interest from the power companies. But they have not yet come up with the $5 million that EPRI says will be needed to develop a commercial system, by making the lasers yet smaller and cheaper. ‘I cannot say I have money yet, but I’m working on it,’ says Bernstein. He reckons that the forthcoming field tests will be the turning point —and he’s hoping for good news. Bernstein predicts ‘an avalanche of interest and support‘ if all goes well. He expects to see cloud-zappers eventually costing $50,000 to $100,000 each.Other scientists could also benefit. With a lightning ‘switch’ at their fingertips, materials scientists could find out what happens when mighty currents meet matter. Diels also hopes to see the birth of ‘interactive meteorology’ —not justforecasting the weather but controlling it. ‘If we could discharge clouds, we might affect the weather,’ he says.And perhaps, says Diels, we’ll be able to conf ront some other meteorological menaces. ‘We think we could prevent hail by inducing lightning,’ he says. Thunder, the shock wave that comes from a lightning flash, is thought to be the trigger for the torrential rain that is typical of storms. A laser thunder factory could shake the moisture out of clouds, perhaps preventing the formation of the giant hailstones that threaten crops. With luck, as the storm clouds gather this winter, laser-toting researchers could, for the first time, strike back.Questions 1-3Choose the correct letter, A, B, C or D.Write the correct letter in boxes 1-3 on your answer sheet.1 The main topic discussed in the text isA the damage caused to US golf courses and golf players by lightning strikes.B the effect of lightning on power supplies in the US and in Japan.C a variety of methods used in trying to control lightning strikes.D a laser technique used in trying to control lightning strikes.2 According to the text, every year lightningA does considerable damage to buildings during thunderstorms.B kills or injures mainly golfers in the United States.C kills or injures around 500 people throughout the world.D damages more than 100 American power companies.3 Researchers at the University of Florida and at the University of New MexicoA receive funds from the same source.B are using the same techniques.C are employed by commercial companies.D are in opposition to each other.Questions 4-6Complete the sentences below.Choose NO MORE THAN TWO WORDS from the passage for each answer.Write your answers in boxes 4-6 on your answer sheet.4 EPRI receives financial support from ..................... .5 The advantage of the technique being developed by Diels is that it can be used.....................6 The main difficulty associated with using the laser equipment is related to its.....................Questions 7-10Complete the summary using the list of words, A-I, below.Write the correct letter, A-I, in boxes 7-10 on your answer sheet.In this method, a laser is used to create a line of ionization by removing electrons from 7 ..................... . This laser is then directed at 8 ..................... in order to control electrical charges, a method which is less dangerous than using 9..................... . As a protection for the lasers, the beams are aimed firstly at10 ..................... .A cloud-zappersB atomsC storm cloudsD mirrorsE techniqueF ionsG rockets H conductors I thunderQuestions 11-13Do the following statements agree with the information given in Reading Passage 1?In boxes 11-13 on your answer sheet writeYES if the statement agrees with the claims of the writerNo if the statement contradicts the claims of the writerNOT GIVEN if it is impossible to say what the writer thinks about this11 Power companies have given Diels enough money to develop his laser.12 Obtaining money to improve the lasers will depend on tests in real storms.13 Weather forecasters are intensely interested in Diels’s system.READING PASSAGE 2You should spend about 20 minutes on Questions 14-26, which are based on Reading Passage 2 below.The Nature of GeniusThere has always been an interest in geniuses and prodigies. The word ‘genius’, from the Latin gens (= family) and the term ‘genius’, meaning ‘begetter’, comes from the ea rly R o m a n c u l t o f a d i v i n i t y a s t h e h e a d o f t h e f a m i l y . I n i t s e a r l i e s t f o r m , g e n i u s w a s c o n c e r n e d w i t h t h e a b i l i t y o f t h e h e a d o f t h e f a m i l y , t h e p a t e r f a m i l i a s , t o p e r p e t u a t e h i m s e l f . G r a d u a l l y , g e n i u s c a m e t o r e p r e s e n t a p e r s o n s c h a r a c t e r i s t i c s a n d t h e n c e a n i n d i v i d u a l s h i g h e s t a t t r i b u t e s d e r i v e d f r o m h i s g e n i u s o r g u i d i n g s p i r i t . T o d a y , p e o p l e s t i l l l o o k t o s t a r s o r g e n e s , a s t r o l o g y o r g e n e t i c s , i n t h e h o p e o f f i n d i n g t h e s o u r c e o f e x c e p t i o n a l a b i l i t i e s o r p e r s o n a l c h a r a c t e r i s t i c s . / p > p b d s f i d = " 1 3 4 " > 0 0 T h e c o n c e p t o f g e n i u s a n d o f g i f t s h a s b e c o m e p a r to f o u r f o l k c u l t u r e , a n d a t t i t u d e s a r e a m b i v a l e n t t o w a r d s t h e m . W e e n v y t h e g i f t e d a n d m i s t r u s t t h e m . I n t h e m y t h o l o g y o f g i f t e d n e s s , i t i s p o p u l a r l y b e l i e v e d t h a t i f p e o p l e a r e t a l e n t e d i n o n e a r e a , t h e y m u s t b e d e f e c t i v e i n a n o t h e r , t h a t i n t e l l e c t u a l s a r e i m p r a c t i c a l , t h a t p r o d i g i e s b u r n t o o b r i g h t l y t o o s o o n a n d b u r n o u t , t h a t g i f t e d p e o p l e a r e e c c e n t r i c , t h a t t h e ya r e p h y s i c a l w e a k l i n g s , t h a t t h e r e s a t h i n l i n eb e t w e e n g e n i u s a n d m a d n e s s , t h a t g e n i u s r u n s i n f a m i l i e s , t h a t t h e g i f t e d a r e s oc l e v e r t h e yd o n t ne e d s p e c i a l h e l p , t h a t g if t e d n e s s i s t h e s a m e a s h a v i ng ahi g h I Q , t h a t s o m e r a c e s a r e m o r e i n t e l l i g e n t o r m u s i c a l o r m a t h e m a t i c a l t h a n o t h e r s , t h a t g e n i u s g o e s u n r e c o g n i s e d a n d u n r e w a r d e d , t h a t a d v e r s i t y m a k e s m e n w i s e o r t h a t p e o p l e w i t h g i f t s h a v e a r e s p o n s i b i l i t y t o u s e t h e m . L a n g u a g e h a s b e e n e n r i c h e d w i t h s u c h t e r m s a s h i g h b r o w , e g g h e a d , b l u e - s t o c k i n g , w i s e a c r e , k n o w - a l l , b o f f i n a n d , f o r m a n y , i n t e l l e c t u a l i s a t e r m o f d e n i g r a t i o n . / p > p b d s f i d = " 1 3 5 " > 0 0 T h e n i n e t e e n t h c e n t u r y s a w c o n s i d e r a b l e i n t e r e s t i n t h e n a t u r e o f g e n i u s , a n d p r o d u c e d n o t a f e w s t u d i e s o f f a m o u s p r o d i g i e s . P e r h a p s f o r u s t o d a y , t w o o f t h e m o s t s i g n i f i c a n t a s p e c t s o f m o s t o f t h e s e s t u d i e s o f g e n i u s a r e t h e f r e q u e n c y w i t h w h i c h e a r l y e n c o u r a g e m e n t a n d t e a c h i n g b y p a r e n t s a n d t u t o r s h a d b e n e f i c i a l e f f e c t s o n t h e i n t e l l e c t u a l , a r t i s t i c o r m u s i c a l d e v e l o p m e n t o f t h e c h i l d re n b u t c a u s e d g r e a t d if f i c u l t i e s o f a d j u s t m e n t l a t e r i n t h e i r l i v e s , a n d t h e f r e q u e n c y w i t h w h i c h a b i l i t i e s w e n t u n r e c og n i s e d b y t e a ch e r s a n d s c h o o l s . H o w e v e r , t h e di f f i c u l t y w i t h t h e e v i d e n c e p r o d u c e d b y t h e s e s t u d i e s , f a s c i n a t i n g a s t h e y a r e i n c o l l e c t i n g t o g e t h e r a n e c d o t e s a n d a p p a r e n t s i m i l a r i t i e s a n d e x c e p t i o n s , i s t h a t t h e y a r e n o t w h a t w e w o u l d t o d a y c a l l n o r m - r e f e r e n c e d . I n o t h e r w o r d s , w h e n , f o r i n s t a n c e , i n f o r m a t i o n i s c o l l a t e d a b o u t e a r l y i l l n e s s e s , m e t h o d s o f u p b r i n g i n g , s c h o o l i n g , e t c . , w e m u s t a l s o t a k e i n t o a c c o u n t i n f o r m a t i o n f r o m o t h e r h i s t o r i c a l s o u r c e s a b o u t h o w c o m m o n o r e x c e p t i o n a l t h e s e w e r e a t t h e t i m e . F o r i n s t a n c e , i n f a n t m o r t a l i t y w a s h i g h a n d l i f e e x p e c t a n c y m u c h s h o r t e r t h a n t o d a y , h o m e t u t o r i n g w a s c o m m o n i n t h e f a m i l i e s o f t h e n o b i l i t y a n d w e a l t h y , b u l l y i n g a n d c o r p o r a l p u n i s h m e n t w e r e c o m m o n a t t h e b e s t i n d e p e n d e n t s c h o o l s a n d , f o r t h e m o s t p a r t , t h e c a s e s s t u d i e d w e r e m e m b e r s o f t h e p r i v i l e g e d c l a s s e s . I t w a s o n l y w i t h t h e g r o w t h o f p a e d i a t r i c s a n d p s y c h o l o g y i n t h e t w e n t i e t h c e n t u r y t h a t s t u d i e s c o u l d b e c a r r i e d o u t o n a m o r e o bj e c t i v e , i f s t i l l n o t a l w a y s v e r y s c i e n t i f i c , b a s i s . / p > p b d s f i d = " 1 3 6 " > 0 0 G e n i u s e s , h o w e v e r t h e y a r e d e f i n e d , a r e b u t t h e p e ak s w h i c h s t a n d o u t t h r o u gh t h e m i s t o f h i s t o r y a n d a r e v i s i b l e t o t h e p a r ti c u l a r o b s e r v e r f r o m h i s o r h e r p a r t i c u l a r v a n t a g e p o i n t . C h a n g e t h e o b s e r v e r s a n d t h e v a nt a g e p o i n t s , c l e a r a w a y s o m e o f t h e m i s t , a n d a d i f f e r e n t l o t o f p e a k s a p p e a r . G e n i u s i s a t e r m w e a p p l y t o t h o s e w h o m w e r e c o g n i s e f o r t h e i r o u t s t a n d i n g a c h i e v e m e n t s a n d w h o s t a n d n e a r t h e e n d o f t h e c o n t i n u u m o f h u m a n a b i l i t i e s w h i c h r e a c h e s b a c k t h r o u g h t h e m u n d a n e a n d m e d i o c r e t o t h e i n c a p a b l e . T h e r e i s s t i l l m u c h t r u t h i n D r S a m u e l J o h n s o n s o b s e r v a t i o n , T h e t r u e g e n i u s i s a m i n d o f l a r g e g e n e r a l p o w e r s , a c c i d e n t a l l y d e t e r m i n e d t o s o m e p a r t i c u l a r d i r e c t i o n . W e m a y d i s a g r e e w i t h t h e g e n e r a l , f o r w e d o u b t i f a l l m u s i c i a n s o f g e n i u s c o u l d ha v eb ec o m e s c i e n t i s t s o f g e n i u s o r v i c e v e r s a ,b u t t h e r e i s n o d o u b t i n g t h e ac c ide n t a l d e t e r m i n a t i o n w h i c h n u r t u r e d o r t r i g g e r e d t h e i r g if t s i n t o t h o s e c h a n n e l s i n t o w h i c h t h e y h a v e p o u r e d t h e i r p o w e r s s o s u c c e s s f u l l y . A l o ng th e c o n ti n u u m o f a b i l i t i e s a r e h u n d r e d s o f t h o u s a n d s o f g i f t e d m e n a n d w o m e n , b o y s a n d g i r l s . / p > p b d s f i d = " 1 3 7 " > 0 0 W h a t w e a p p r e c i a t e , e nj o y o r m a r v e l a t i n t h e w o rk s o f g e n i u s o r t h e a c h i e v e m e n t s o f p r o d i g i e s a r e t h e m a n i f e s t a t i o n s o f s k il l s o r a b i l i t i e s w h i c h a r e s im i l a r t o , b u t s o m u c h s u p e r i o r t o , o u r o wn . B u t t h a t t h e i r m i n d s a r e no t d i f f e r e n t f r o m o u r o w n i s d e m o n s t r a t e d b y t h e f a c t t h a t t h e h a r d - w o n d i s c o v e r i e s o f s c i e n t i s t s l i k e K ep l e r o r E i n s t e i n b e c o m e t h e c o m m o n p l a c e k n o w l e d g e o f s c h o o l c h i l d r e n a n d t h e o n c e o u t r a g e o u s s h a p e s a n d c o l o u r s o f a n a r t i s t l i k e P a u l K l e e s o s o o n a p pe a r o n t h ef a b r i c s w e w e a r . T h i s d o e s n o t m i n i m i s e t h e s u p r e m a c y o f t h e i r a c h i e v e m e n t s , w h i c h o u t s t r i p o u r o w n a s t h e s u b - f o u r - m i n u t e m i l e r s o u t s t r i p o u r j og g i n g . / p > p b d s f i d = " 1 3 8 " > 0 0 T o thi n k o f g e n i u s e s a n d t h e g i f t e d a s h a v i n g u n i q u e l y d i f f e r e n t b r a i n s i s o n l y r e a s o n a b l e i f w e a c c e p t t h a t e a c h h u m a n b r a i n i s u n i q u e l y d i f f e r e n t . T h e p u r p o s e o f i n s t r u c t i o n i s t o m a k e u s e v e n m o r e d i f f e r e n t f r o m o n e a n o t h e r , a n d i n t h e p r o c e s s o f b e i n g e d u c a t e d w e c a n l e a r n f r o m t h e a c h i e v e m e n t s o f t h o s e m o r e g i f t e d t h a n o u r s e l v e s . B u t b e f o r e w e t r y t o e m u l a t e g e n i u s e s o r e n c o u r a g e o u r c h i l d r e n t o d o s o w e s h o u l d n o t e t h a t s o m e o f t h e t h i n g s w e l e a r n f r o m t h e m m a y p r o v e u n p a l a t a b l e . W e m a y e n v y t h e i r a c h i e v e m e n t s a n d f a m e , b u t w e s h o u l d a l s o r e c o g n i s e t h e p r i c e t h e y m a y h a v e p a i d i n t e r m s o f p e r s e v e r a n c e , s i n g l e - m i n d e d n e s s , d e d i c a t i o n , r e s t r i c t i o n s o n t h e i r p e r s o n a l l i v e s , t h e d e m a n d s u p o n t h e i r e n e r g i e s a n d t i m e , a n d h o w o f t e n t h e y h a d t o d i s p l a y g r e a t c o u r a g e t o p r e s e r v e t h e i r i n t e g r i t y o r t o m a k e t h e i r w a y t o t h e t o p . / p > p b d s f i d = " 1 3 9 " > 0 0 G e n i u s a n d g i f t e d n e s s a r e r e l a t i v e d e s c r i p t i v e t e r m s o f n o r e a l s u b s t a n c e . W e m a y , a t b e s t , g i v e t h e m s o m e p r e c i s i o n b y d e f i n i n g t h e m a n d p l a c i n g t h e m i n a c o n t e x t b u t , w h a t e v e r w e d o , w e s h o u l d n e v e r d e l u d e o u r s e l v e s i n t o b e l i e v i n g t h a t g i f t e d c h i l d r e n o r g e n i u s e s a r e d i f f e r e n t f r o m t h e r e s t o f h u m a n i t y , s a v e i n t h e d e g r ee t o w h i c h t h e y h a v e d e v e l o p e d t h e p e rf o r m a n c e o f t h e i r a b i l i t i e s . / p > p b d s f i d = " 1 4 0 " > 0 0 Q u e s t i o n s 1 4 - 1 8 / p > p b d s f i d = " 1 4 1 " > 0 0 C h o o s e F I V E l e t t e r s , A - K . / p > p b d s f i d = " 1 4 2 " > 0 0 W r i t e t h e c o r r e c t l e t t e r s i n b o x e s 1 4 - 1 8 o n y o u r a n s w e r s h e e t . / p > p b d s f i d = " 1 4 3 " > 0 0 N B Y o u r a n s w e r s m a y b eg i v e n i n a n y o r d e r . / p > p b d s f i d = " 1 4 4 " > 0 0 B e l o w a r e l i s t e d s o m e p o p u l a r be l i ef s a b o u tg e n i u s a n d g i f t e d n e s s . / p > p b d sf i d = " 1 4 5 " > 0 0 W h i c h F I V E o f t h e s e b e l i e f s a r e r e p o r t e d b y t h e w r i t e r o f t h e t e x t ? / p > p b d s f i d = " 1 4 6 " > 0 0 A T r u l yg i f t e d p e o p l e a r e t a l e n t ed i n a l l a re a s . / p > p b d sf i d = " 1 4 7 " > 0 0 B T h e t a le n t s ofg e n i u s e s a r e s o o n e xh a u s t e d . / p > p b d s fi d = " 1 4 8 " > 0 0 C G i f t e d p e o p l e s h o u l d u s e t h e i r g i f t s . / p > p b d s f i d = " 1 4 9 " > 0 0 D A g e n i u s a p p e a r s o n c e i n e v e r y g e n e r a t i o n . / p > p b d s f i d = " 1 5 0 " > 0 0 E G e n i u s c a n b e e a s i l y d e s t r o y e d b yd i s c o u r a ge m e n t . / p > p b d sf i d = " 1 5 1 " > 0 0 F Ge n i u s i s i n h e r i t e d . / p > p b d sf i d = " 1 5 2 " > 0 0 G G i f t e d p e o p l e a r e v e r y h a r d t o l i v e w i t h . / p > p b d s f i d = " 1 5 3 " > 0 0 H P e o p l e n e v e r a p p r e c i a t e t r u eg e n i u s . / p > p b d s f i d = " 1 5 4 " > 0 0 I G e n i u s e s a r e n a t u r a l l e a d e r s . / p > p b d s f i d = " 1 5 5 " > 0 0 J G i f t e d p e o p l e d e v e l o p th ei r g r e a t n e s s t h r o u g h d i f f i c u l t i e s . / p > p b d s f i d = " 1 5 6 " > 0 0 K G e n i u s w i l l a l w a y s r e v e a l i t s e l f . / p > p b d s f i d = " 1 5 7 " > 0 0 Q u e s t i o n s 1 9 - 2 6 / p > p b d s f i d = " 1 5 8 " >0 0 D o t h e f o l l o w i n g s t a t e m e n t s a g r e e w i t h t he i nf o r m a t i o ng i v e n i n R e a d i n g P a s s a g e 2 ? / p >p b d s f i d = " 1 5 9 " > 0 0 I n b o x e s 1 9 - 2 6 o n y o u r a n s w e r s h e e t , w r i t e / p > p b d s f i d = " 1 6 0 " > 0 0 T R U E i f t h e s t a t e m e n t a g r e e s w i t h t h e i n f o r m a t i o n / p > p b d s f i d = " 1 6 1 " > 0 0 F A L S E i f t h e s t a t e m e n t c o n t r a d i c t s t h e i n f o r m a t i o n / p > p b d s f i d = " 1 6 2 " > 0 0 N O T G I V E N i f t h e r e i s n o i n f o r m a t i o n o n t h i s / p > p b d s f i d = " 1 6 3 " > 0 0 1 9 N i n e t e e n t h - c e n t u r y s t u d i e s o f t h e n a t u r e o f g e n i u s f a i l e d t o t a k e i n t o a c c o u n t t h e u n i q u e n e s s o f t h e pe r s o n s u p b r i n g i n g . / p > p b d sf i d = " 1 6 4 " > 0 0 20 N i n e t e e n t h - c e n t u r y s t u d i e s o f g e n i u s l a c ke d b o t h o b j e c t i v i t y a n d a p r o p e r s c i e n t if i c a p p r o a c h . / p > p b d s f i d = " 1 6 5 " > 0 0 2 1 A t r u eg e n i u sh a s g e n e r a l p o w e r s c a p a b l e o f e x c e l l e n c ei n a n y a r e a . / p > p b d s f i d = " 1 6 6 " > 0 0 2 2 T h e s k i l l s o f o r d i n a r y i n d i v i d u a l s a r e i n e s s e n c e t h e sa m e a s t h e s k i l l s o f p r o d i g i e s . / p > pb d s f i d = "1 6 7 " > 0 023 T h e e a s e w i t h w h i c h t r u l y g r e a t i de a s a r e a c c e p t e d a n d t a k e nf o rg r a n t e d f a i l s t o l e s s e n th ei r s i g n i f i c a n c e . / p > p b d s f i d = " 1 68 " > 0 0 2 4 G i f t e d n e s s a n d g e n i u s d e s e r v e p r o pe r s c i e n t if i c r e s e a r c h i n t o t h e i r t r u e n a t u r e s o t h a t a l l t a l e n t m a y b e r e t a i n e d f o r t h e h u m a n r a c e . / p > p b d s f i d = " 1 6 9 " > 0 0 2 5 G e n i u s e s o f t e n p a y a h igh p ri c e t o a c h i e v e g r e a t n e s s . / p > p b d s f i d = " 1 7 0 " > 0 0 2 6 T o b e a g e n i u s i s w o r t h t h e h i g h p e r s o n a l c o s t . / p > p b d s f i d = " 1 7 1 " > 0 0 R E A D I N G P A S S A G E 3 / p > p b d s f i d = " 1 7 2 " > 0 0 Y o u s h o u l d s p e n d a b o u t 2 0 m i n u t e s o n Q u e s t i o n s 2 7 - 4 0 , w h i c h a r e b a s e d o n R e a d i n g P a s s a g e3 o n t h e f o l l o w i n g p a g e s . / p > p b d s f i d = " 1 7 3 " >0 0 Q u e s t i o n s 2 7 - 3 2 / p > p b d s f i d = " 1 7 4 " > 0 0 Re a d i n g P a s s a g e 3 h a s s e v e n p a r a g r a p h s , A - G . / p > p b d sf i d = " 1 7 5 " > 0 0 C h o o s e t h e c o r r e c t h e a d i ng f o r p a r a g r a ph s B - G f r o m t h e li s t o f h e a d i n g s b e l o w . / p > p b d s f i d = " 1 7 6 " > 0 0 W r i t e t h e c o r r e c t n u m b e r , i - x , i n b o x e s 2 7 - 3 2 o n y o u r a n s w e r s h e e t . / p > p b d s f i d = " 1 7 7 " > 0 0 L i s t o f H e a d i n g s / p > p b d s f i d = " 1 7 8 " > 0 0 i T h e b i o l o g i c a l c l o c k / p > p b d s f i d = " 1 7 9 " > 0 0 i i W h y d y i n g i s b e n e f i c i a l / p > p b d s f i d = " 1 8 0 " > 0 0 i i i T h e a g e i n g p r o c e s s o f m e n a n d w o m e n / p > p b d s f i d = " 1 8 1 " > 0 0 i v P r o l o n g i n g y o u r l i f e / p > p b d s f i d = " 1 8 2 " > 0 0 v L i m i t a t i o n s o f l i f e s p a n / p > p b d s f i d = " 1 8 3 " > 0 0 v i M o d e s o f d e v e l o p m e n t o f d i f f e r e n t s p e c i e s / p > p b d s f i d = " 1 8 4 " > 0 0 v i i A s t a b l e l i f e s p a n d e s p i t e i m p r o v e m e n t s / p > p b d s f i d = " 1 8 5 " > 0 0 v i i i E n e r g y c o n s u m p t i o n / p > p b d s f i d = " 1 8 6 " > 0 0 i x F u n d a m e n t a l d i f f e r e nc e s i n a g e i n g o f o b j e c t s a nd o r g a n i s m s / p > p bd s f i d = " 1 8 7 " > 0 0 x Re p a i r ofg e n e t i c m a t e r i a l / p > p b d s f i d = " 1 8 8 " > 0 0 E x a m p l e A n s w e r / p > p b d s f i d = " 1 8 9 " > 0 0 P a r a g r a ph A v / p > p b d s fi d = " 1 9 0 " > 0 0 2 7 P a r a g r a p h B / p > p b d s f i d = " 1 9 1 " > 0 0 2 8 P a r a g r a p h C / p > p b d s f i d = " 1 9 2 " > 0 0 29 P a r a g r a p h D / p > p b d s f i d = " 1 9 3 " > 0 0 3 0 P a r ag r a p h E / p > p b d s f i d = " 1 9 4 " > 0 0 3 1 P a r a g r a p h F / p > p b d s f i d = " 1 9 5 " > 0 0 3 2 P a r a g r a p h G / p > p b d s f i d = " 1 9 6 " > 0 0 H O W D O E S T H E B I O L O G I C A L C L O C K T I C K ? / p > p b d s f i d = " 1 9 7 " > 0 0 A O u r l if e s p a n i s r e s t r i c t e d . E v e r y o n e a c c e p t s t h i s a s b i o l og i c a l l y o b v i o u s . N o thi n g l i v e s f o r e v e r !H o w e v e r , i n t h i s s t a t e m e n t w e t h i n k o f a r t i f i c i a l l y p r o d u c e d , t e c h n i c a l o b j e c t s , p r o d u c t s w h i c h a r e s u b j e c t e d t o n a t u r a l w e a r a n d t e a r d u r i n g u s e . T h i s l e a d s t o t h e r e s u l t t h a t a t s o m e t i m e o r o t h e r t h e o b j e c t s t o p s w o r k i n g a n d i s u n u s a b l e ( d e a t h i n t h e b i o l o g i c a l s e n s e ) . B u t a r e t h e w e a r a n d t e a r a n d l o s s o f f u n c t i o n o f t e c h n i c a l o b j e c t s a n d t h e d e a t h o f l i v i n g o r g a n i s m s r e a l l y s i m i l a r o r c o m p a r a b l e ? / p > p b d s f i d = " 1 9 8 " > 0 0 B O u r d e a d p r o d u c t s a r e s t a t i c , c l o s e d s y s t e m s . I t i s a l w a y s t h e b a s i c m a t e r i a l w h i c h c o n s t i t u t e s t h e o b j e c t a n d w h i c h , i n t h e n a t u r a l c o u r s e o f t h i n g s , i s w o r n d o w n a n d b e c o m e s o l d e r . A g e i n g i n t h i s c a s e m u s t o c c u r a c c o r d i n g t o t h e l a w s o f p h y s i c a l c h e m i s t r y a n d o f t h e r m o d y n a m i c s . A l t h o u g h t h e s a m e l a w h o l d s f o r a l i v i n g o r g a n i s m , t h e r e s u l t o f t h i s l a w i s n o t i n e x o r a b l e i n t h e s a m e w a y . A t l e a s t a s l o n g a s a b i o l o g i c a l s y s t e m h a s t h e a b i l i t y t o r e n e w i t s e l f i t c o u l d a c t u a l l y b e c o m e o l d e r w i t h o u t a g e i n g ; a n o r g a n i s m i s a n o p e n , d y n a m i c s y s t e m t h r o u g h w h i c h n e w m a t e r i a l c o n t i n u o u s l y f l o w s . D e s t r u c t i o n o f o l d m a t e r i a l a n d f o r m a t i o n o f n e w m a t e r i a l a r e t h u s i n p e r m a n e n t d y n a m i c e q u i l i b r i u m . T h e m a t e r i a l o f w h i c h t h e o r g a n i s m i s f o r m e d c h a n g e s c o n t i n u o u s l y . T h u s o u r b o d i e s c o n t i n u o u s l y e x c h a n g e o l d s u b s t a n c e f o r n e w , j u s t l i k e a s p r i n g w h i c h m o r。

【参考文档】剑桥雅思真题集5阅读部分分析3-实用word文档本文部分内容来自网络整理，本司不为其真实性负责，如有异议或侵权请及时联系，本司将立即删除！== 本文为word格式，下载后可方便编辑和修改！ ==剑桥雅思真题集5阅读部分分析3本辑中将特别推出剑桥雅思5 Test 4 的第二篇文章的解析。

这篇文章的内容是有关强化玻璃的，在201X-201X年的考试中多次出现，是在亚洲考区考试频率最高的考题之一。

其出题的学术性和教学的实用性都非常的突出。

首先关注的是这篇考题的布局。

先出现的四题是人名观点配对题。

接下来的六题是概括归纳题。

最后则是必考题型是非无判断题。

这三类题目全都是细节信息，主要考察学生的信息搜索能力和语言转换的能力。

同时，在短时间内完成所有的题目的能力也对考生提出了较高的要求。

第一种人名观点配对题和大多数考试的出题方式有些许的不同。

以往的考试真题中的出题方式都是以人名作为选项，而把观点作为题目的。

这样一来，就导致了人名作为选项极有可能产生多选的状况。

这样一来就增加了做题的时间和难度。

而在强化玻璃这篇阅读题目中，人名则作为了题目，而观点则放到了选项当中，因此，一个观点配多个人名的可能性就极小了。

但是这样一来会导致另外一个难点：题目和选项都不按照顺序原则出现。

从而对于考生的信息搜索能力的要求就大幅增加了。

作为雅思阅读的讲师来说，对于这篇文章的教学中要充分讲解该考题的难度和学生的做题方法。

在阅读文章中，会出现超过题目中的人名的数量，也会产生相当多的干扰项。

如何排除干扰以及指导学生科学的阅读方法是每个教师在讲解这篇文章的考试技巧时的重要一环!。

雅思剑桥9阅读解析
剑桥雅思9是备考雅思阅读部分的重要参考资料。

本书的阅读材料涵盖了多个话题，如科学、历史、文化等，考察了考生的阅读理解能力和解题技巧。

下面将对剑桥雅思9中的阅读部分进行详细解析。

本书的阅读部分由三篇阅读文章组成，每篇文章后都有对应的习题。

文章内容涵盖了不同的难度和题型，能够帮助考生全面掌握阅读技巧。

第一篇文章主要讲述了关于环保的话题。

文章通过介绍澳大利亚面对的环境问题以及政府采取的措施，引导考生理解和掌握环保方面的重要信息，并进行相关问题的解答。

第二篇文章主要谈论了动物迁徙的现象。

文章中给出了一些动物迁徙的具体实例，如鸟类、鲨鱼等，考察考生对动物迁徙原因和方式的理解。

考生需要从文章中获取相关信息，并回答相应的问题。

第三篇文章是一篇历史方面的文章，介绍了欧洲中世纪的风车。

文章探讨了风车在农业和工业发展中的重要作用，从而帮助考生理解欧洲中世纪社会的一些特点和变迁。

在解析这些文章时，我的建议是，首先通读全文，把握整体内容；然后细读每一段，理解段落的主题和关键信息；最后回答习题时，注意审题，并参考文章中的具体信息进行答题。

剑桥雅思9的阅读部分是一份很好的备考资料，通过对其中的文章进行仔细解析和练习，考生可以提高自己的阅读能力和解题技巧，为取得良好的雅思阅读成绩奠定基础。

剑桥雅思5Test2雅思阅读Passage3题目+答案+解析更多真题解析，请点击：剑桥雅思5阅读解析。

剑桥雅思5真题下载，请点击：。

Question 28答案： Latin关键词：Europe/nation state/At first定位原文: 文中第1、5、6段解题思路: 在首段末句，作者提到了 Before that, Latin was regarded as the lingua franca for European intellectuals. 我们隐约可以感觉到拉丁文在学术界的盛行，但这还不足以让我们确定此空就要填Latin一词。

在第五和第六段中，作者提到了学术界流行拉丁文的原因。

其中第六段开头一句提到A second reason for writing in Latin may, perversely, have a concern for secrecy. 这正好就等同题目中28空后面的那句话，所以我们椎测答案应该填写Latin一词。

Question 29答案： doctors关键词： Mathematicians定位原文: 第6段中最后3句解题思路: 题目中告诉我们：有的时候保护个人观点的欲望远远大于与人分享观点的欲望，特别是对于数学家和___。

在这里应该填上一个表示职业的名词。

而第六段中在mathematician 之后，只有一个表示职业的名词，那就是doctors。

故答案应该填 doctors。

Question 30 and Question 31答案： technical vocabulary grammatical resources (in either order)关键词： Britain/ English/ neither... nor...定位原文: 第7段第3句“First, it lacked…”解题思路: 首先用English将此题定位在第七段中，这一段提到了英文为什么迟迟未被用作学术语言的原因。