1. What does Lily suggest Mr. Stenson doing?
A.Using the pesticide. | B.Changing the crop. | C.Watering the fields. |
A.He often shares his products. |
B.He lives far from Lily. |
C.He is good at farming. |
1. How many people died in a landslide in 2003?
A.About two hundred. | B.Over one thousand. | C.About two thousand. |
A.Growing grass. | B.Cutting down trees. | C.Growing population. |
A.Growing more forests. |
B.Chopping down the old forests. |
C.Getting busy in protecting our country. |
1. How does the woman feel at first?
A.Curious. | B.Surprised. | C.Excited. |
A.Flowers. | B.Mushrooms. | C.Trees. |
A.Two. | B.Three. | C.Four. |
A.On Thursday. | B.On Friday. | C.On Saturday. |
4 . Scientists have been experimenting with playing sounds to plants since at least the 1960s, during which time they have been exposed to everything from Beethoven to Michael Jackson. Over the years, evidence that this sort of thing can have an effect has been growing. One paper, published in 2018, claimed that an Asian shrub known as the telegraph plant grew substantially larger leaves when exposed to 56 days of Buddhist music — but not if it was exposed to Western pop music or silence. Another, published last year, found that marigolds and sage plants exposed to the noise of traffic from a busy motorway suffered growth difficulty.
Plants have been evolving (进化) alongside the insects that eat them for hundreds of millions of years. With that in mind, Heidi Appel, a botanist now at the University of Houston, and Reginald Cocroft, a biologist at the University of Missouri, wondered if plants might be sensitive to the sounds made by the animals with which they most often interact. They recorded the vibrations made by certain species of caterpillars (毛毛虫) as they chewed on leaves. These vibrations are not powerful enough to produce sound waves in the air. But they are able to travel across leaves and branches, and even to neighbouring plants if their leaves touch.
They then exposed tobacco plant — the plant biologist’s version of the laboratory mouse — to the recorded vibrations while no caterpillars were actually present. Later, they put real caterpillars on the plants to see if exposure had led them to prepare for an insect attack. The results were striking. Leaves that had been exposed had significantly higher levels of defensive chemicals, making them much harder for the caterpillars to eat. Leaves that had not been exposed to vibrations showed no such response. Other sorts of vibration — caused by the wind, for instance, or other insects that do not eat leaves — had no effect.
“Now speakers with the right audio files are more often being used to warn crops to act when insects are detected but not yet widespread,” says Dr. Cocroft. “Unlike chemical pesticides, sound waves leave no dangerous chemicals.”
1. What can we learn about plants from the first paragraph?A.They may enjoy Western music. | B.They can’t stand Buddhist music. |
C.They can react to different sounds. | D.They can make different sounds. |
A.Plants can make a cry for help. | B.Plants evolve alongside insects. |
C.Plants are sensitive to the sounds. | D.Plants have been studied for years. |
A.They can recongnize harmful vibrations. | B.They look like laboratory mice. |
C.They can threaten the caterpillars. | D.They can release poisonous chemicals. |
A.Disadvantages of chemical pesticides. | B.Application of the experimental results. |
C.Interaction between plants and insects. | D.Warning system of widespread insects. |
When John pulled into his mother’s driveway with his young daughter, Lily, the sight of the familiar lychee (荔枝) tree welcomed them. “Look, Lily,” John said, pointing to the towering tree in the front yard. “It’s the family tree.”
Lily smiled as John treated the tree as if it were a real family member, patting its trunk (树干) affectionately. As they were admiring the tree, the screen door opened and out stepped Grandma Mei, bathed in the warm Florida sunlight. Grandma Mei, who came from the province of Guangdong in China, was known for her green thumb, particularly when it came to lychees.
Seeing her granddaughter, Grandma Mei adjusted her baseball cap and asked if Lily was ready for some lychees. But Lily hesitated, for the fruit’s appearance was unlike any other fruit she had tried before. With a laugh, Grandma Mei gave her a gentle hug. “More lychees for me then, John,” Grandma Mei said.
“Let’s get busy!” John said with enthusiasm, rubbing his hands together. “Family tree’s waiting.”
Hearing Dad calling the tree by name, Lily couldn’t help laughing. “Laugh if you want, Lily, but this tree is really family. On cold nights, before family tree was fully grown, Grandma Mei used to take my blanket and throw it over that tree.” Grandma Mei nodded, adding that she had to protect the tree from bad weather so that it would become a big strong tree and grow fruit for the whole family.
John, eager to start the day’s work, began climbing the tree, determined to harvest the best lychees for the family. Lily watched in amazement, noticing the clusters (簇) of lychees, their skin rough yet inviting.
As John skillfully cut through the branches with a cutter, Lily expressed her concern for the well-being of the tree. John explained to her that cutting the ends of branches won’t hurt family tree. Instead such behaviour made it healthier and stronger.
注意:
1.续写词数应为150左右;
2.请按如下格式在答题卡的相应位置作答。
Lily’s hesitation towards the fruit gradually shifted to curiosity and she wanted to try it.
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Later in the afternoon, they all sat under the tree, surrounded by boxes filled with lychees and sharing stories related to lychees.
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6 . Scientists have shown how plants can protect themselves against genetic (基因的) damage caused by environmental stresses. The growing tips of plant roots and shoots have an in-built mechanism (机制) that spells cell death if DNA damage is detected, avoiding passing on faulty DNA.
Plants have small populations of stem cells (干细胞) at the tips of their roots and shoots, which enable them to continuously grow and produce new tissues throughout their lifetime. These stem cells serve as ancestors for plant tissues and organs. However, any genetic faults present in the stem cells will continue to exist and be passed on permanently throughout the plant’s life, which could last thousands of years.
Given the critical role of stem cells and their exposure to potentially dangerous environments at the growing tips of roots and shoots, safeguards are necessary to prevent stem cell faults from becoming fixed. Researchers Nick Fulcher and Robert Sablowski, funded by the Biotechnology and Biological Sciences Research Council, aimed to uncover these protective mechanisms. Through experiments involving X-rays and chemicals, they discovered that stem cells were more sensitive to DNA damage compared to other cells.
When DNA damage occurs, the cells have the capacity to detect it and cause programmed cells to die, preventing the propagation of the damaged genetic code to the rest of the plant tissues. This process has similarities to the safeguard mechanism found in animal cells, which has been broadly studied due to its relevance in preventing cancer.
The identification of a similar protective system in plants is of great interest in the field of plant development. It also helps scientists develop plants that can better handle environmental stress. So knowledge of how plants deal with these stresses is of fundamental significance to agricultural science’s response to climate change.
1. What is the function of the in-built mechanism in plants?A.To produce more roots and shoots. | B.To increase the overall lifetime of the plant. |
C.To enhance plant growth and nutrient intake. | D.To stop genetic faults in stem cells passing on. |
A.They are relatively abundant in quantity. | B.They are resistant to environmental stresses. |
C.They make quick response to DNA damage. | D.They have the ability to repair damaged DNA. |
A.Spread. | B.Change. | C.Existence. | D.Self-repair. |
A.The way of dealing with climate change on the earth. |
B.The significance of identifying the protective system in plants. |
C.The method of ensuring plant survival under environmental stress. |
D.The urgency of developing plants that can handle environmental stress. |
7 . Plants do not suffer in silence when thirsty or stressed, according to a new study published today in Cell.
Plants that need water or have recently had their branches cut produce up to roughly 35 sounds per hour, the authors found. But well-watered and uncut plants are much quieter, making only about one sound per hour.
The reason why you have probably never heard a thirsty plant make noises is that the sounds are so high-pitched that very few humans could hear them. Some animals, however, probably can. Bats, mice and moths could possibly live in a world filled with the sounds of plants, and previous work by the same team has found that plants respond to sounds made by animals, too.
To overhear plants, Lilach Hadany at Tel-Aviv University in Israel and her colleagues placed tobacco and tomato plants in small boxes provided with microphones. The microphones picked up any noises made by the plants, even if the researchers couldn’t hear them. The noises were particularly obvious for plants that were stressed by a lack of water or recent cutting.
Plants do not have vocal cords (声带) or lungs. Hadany says the current theory for how plants make noises centers on their xylem (木质部) that transport water and nutrients from their roots to their branches and leaves. Water in the xylem is held together by surface tension, just like water moving through a drinking straw. If an air bubble (气泡) forms or breaks in the xylem, it might make a little popping noise; bubble formation is more likely during dry seasons. But the exact system requires further study, Hadany says.
The team produced a machine-learning model to check whether a plant had been cut or was water-stressed from the sounds it made, with about 70% accuracy. This result suggests a possible role for the audio monitoring of plants in farming and gardening.
To test the practicality of this approach, the team tried recording plants in a greenhouse. Pilot studies by the authors suggest that tomato and tobacco plants are not exception. Wheat, corn and wine grapes also make noises when they are thirsty.
1. What is the new research mainly about?A.Plants can react to animals. | B.Plants can produce sounds. |
C.Well-watered plants keep silent. | D.Branchless plants need watering. |
A.They can create more bubbles. | B.They can feel less stressed. |
C.They require less nutrient supply. | D.The y need lungs to breathe more. |
A.Fruit growing. | B.Crop selection. |
C.Water source protection. | D.Noise pollution test. |
A.How Plants Are Thirsty | B.When Nature Expresses Itself |
C.How Plants Cry for Their Needs | D.When Creatures Hear Each Other |
8 . As Earth’s climate continues to change, a plant’s ability to adapt to its changing environment is important to its survival. Often, to stay alive, a plant must move locations by releasing its seeds, but plants are rooted in the ground and cannot move themselves. Instead, they are dependent on animals or the wind to carry their seeds to a new location.
Playing an essential part in an ecosystem (生态系统), plants create resources like food and medicine for us human beings. A team of researchers developed the model to better understand how plants can stay resiliency (韧性) when facing challenges like climate change.
“Once seeds are released from a plant, we wanted to know how far they can go because as wind conditions shake, the seeds will be moved around differently because of various weights, sizes, and shapes,” says Binbin Wang, an assistant professor at the University of Missouri.
Changes in one part of the ecosystem can create a “snowball effect” on other parts. That’s why understanding seed spread is important. Plants can only make this move once during their life — as a seed, says Lauren Sullivan, an assistant professor at Michigan State University.
“Understanding how plants move as seeds year-round is important for us to analyze how they’ll be able to handle climate change,” Sullivan says. “This movement is also important for how we can increase diversity (多样性) in the ecosystem.” “We’re now able to partner with researchers. This innovative approach can help us develop accurate models that are simple enough to make good predictions in a short time.”
The model, which makes predictions based on seed and plant type, plant height, and wind speed, can develop an entire year’s worth of predictive data in just one or two days. As part of their future work, the team will develop educational programming for K-12 and college students. For example, they will provide opportunities for college students to explore how different disciplines, such as agriculture, biological sciences, and engineering, can work together to solve different real-world problems.
1. Why did the researchers develop the model?A.To learn how plants handle challenges like climate change. |
B.To find out what helps seeds travel to different places. |
C.To study the effects climate change has on plants. |
D.To create more food and medicine resources. |
A.Its weight. | B.Its location. | C.Its size. | D.Its shape. |
A.It is caused by the change of the climate. |
B.It can happen during the whole life of a plant. |
C.It has an effect on other parts of the ecosystem. |
D.It’s hard to be predicted for the diversity of ecosystem. |
A.Explore different disciplines for college students. |
B.Work together to solve different real-world problems. |
C.Develop educational programming for students to explore. |
D.Make valuable predictions about the type and height of the plants. |
1. What makes potted roses easier to plant?
A.Lower nutrition requirement. |
B.Stronger cold resistance. |
C.Better root development. |
A.They need less soil. |
B.They are easier to transport. |
C.Their planting time is fixed. |
A.Damp condition. | B.Heavy sunshine. | C.Continuous watering. |
A.Types of roses. | B.Ways of rose packing. | C.Tips on rose growing. |
Scientists in Florida have
According to Professor Anna-Lisa Paul, all the plants looked the same
DNA testing showed that those Thale Cress 2
NASA Administrator Bill Nelson believes this research will help future space missions and that resources on the moon and Mars