1 . Animal appear to predict earthquakes by sensing electricity in the air — the first study to find reliable evidence of the phenomenon has shown.
Cameras revealed an “amazing” drop in the number of animals up to 23 days before a major quake hit their rainforest home at Yanachaga National Park in Peru. Lead scientist Dr Rachel Grant, from Anglia Ruskin University, said, “The results showed that just before the earthquake, animals’ activity dropped right down.”
On a normal day the cameras placed around Yanachaga National Park record between 5 and 15 animals. But in the 23 days before the earthquake, the number of animals dropped to five or fewer per day. No animals were photographed at all on five of the seven days immediately before the quake.
Another study showed that animal activity remained normal in the park over a different period when seismic (地震的) activity was low. Co-author, professor Friedemann Freund, said, “The cameras were located at an altitude of 900 meters. If air ionization occurred, the animals would escape to the valley below, where there were fewer positive ions ( 离子). With their ability to sense their environment, animals can help us understand small changes that occur before major earthquakes.”
Other evidence suggested that before the earthquake, the air around the high mountain sites filled with positive ions that can be produced when rocks are placed under stress. Positive ions have been known to cause ill effects in humans as well as animals. Scientists believe the animals were made to feel uncomfortable by the positive ions, leading them to avoid the area. They are thought to have escaped to lower ground, where the air was less ionized. The findings may help experts develop better short-term seismic forecasts.
1. How did scientists conduct the study?A.By comparing different animals’ habits. |
B.By observing animals in high mountains. |
C.By explaining the positive ion phenomenon. |
D.By analyzing images of animals they obtained. |
A.The ground at a lower altitude is less ionized. |
B.Cameras normally record more animals per day. |
C.Earthquake warnings can be detected in lower places. |
D.The activity of animals and earthquakes is consistent. |
A.The findings make for accurate seismic forecast. |
B.Animals tend to be uneasy with more positive ions. |
C.Positive ions make humans and animals depressed. |
D.All the animals remain abnormal before the earthquake. |
A.Negative Influence of Positive Ions. |
B.Ions’ Destruction to the Environment. |
C.Animals’ Behavior Before Earthquakes. |
D.Creatures’ Ability to Predict Earthquakes. |
1.表达歉意;
2.解释原因;
3.已将志愿工作安排他人完成。
注意:
1.写作词数应为80左右;
2.请在答题卡的相应位置作答。
Dear Mr. George,
____________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________________
Yours,
Li Hua
3 . The history of microbiology begins with Dutch cloth maker named Antoni van Leeuwenhoek, a man of no formal scientific education. In the late 1600s. Leeuwenhoek, inspired by the magnifying lenses(放大镜)he used to examine cloth, built some of the first-microscopes. He developed technique to improve the quality of tiny, rounded lenses, some of which could magnify an object up to 270 times. After removing some plaque from between his teeth and examining it under a lens, Leeuwenhoek found tiny twisting creatures, which he called “animalcules”.
His observations, which he reported to the Royal Society of London, are among the first descriptions of microbes(微生物). Leeuwenhoek discovered an entire universe invisible to the human eye. He found different microbes in samples of pond water, rain water, and human blood. He gave the first description of red blood cells, observed plant tissue, examined muscle, and investigated the life cycle of insects.
Nearly two hundred years later, Leeuwenhock’s discovery of microbes helped French chemist and biologist Louis Pasteur to develop his “theory of disease”. This concept suggested that disease originates from tiny organisms attacking and weakening the body. Pasteur’s theory later helped doctors to fight infectious diseases including anthrax, diphtheria, polio, smallpox, tetanus, and typhoid. All these breakthroughs were the result of Leeuwenhoek’s original work. Leeuwenhoek did not foresee this legacy.
In a 1716 letter, he described his contribution to science this way: “My work, which I’ve done for a long time, was not pursued in order to gain the praise I now enjoy, but chiefly from a strong desire for knowledge, which I notice resides in me more than in most other men. And therefore; whenever I found out anything remarkable, I have thought it my duty to put down my discovery on paper, so that the scientific community might be informed thereof.”
1. Which of the following best describes Leeuwenhoek?A.trained researcher with an interest in microbiology |
B.A curious amateur who made pioneer studies of microbes |
C.A talented scientist interested in finding a cure for disease |
D.A bored cloth maker who accidentally made a major discovery |
A.the discovery of microbes |
B.Pasteur’s theory of disease |
C.Leeuwenhoek’s contribution |
D.the origin of the tiny organism |
A.He admitted that many of his discoveries happened by chance. |
B.He considered his work to be central to later medical breakthroughs. |
C.He was greatly concerned with improving people’s living conditions. |
D.He believed the sharing of knowledge was a key to scientific progress |
a. Magnifying lenses were built.
b. The “theory of disease” was put forward
c. Microbes were discovered in samples of waters.
d. Leeuwenhoek’s first microscopes were successfully developed.
e. Leeuwenhoek explained his thoughts upon his own contribution.
A.a-d-c-e-b | B.d-a-c-e-b | C.a-c-d-b-e | D.d-a-e-b-c |