1 . Indoor plants might look as if they just sit around not doing much, but in many ways they are the unsung heroes of the home.
What are indoor plants?
Indoor plants, also known as houseplants or pot plants, are plants that like to grow indoors. Many of these species (物种) are not ideally suited to growing outside in the UK, especially in the winter.
Why are indoor plants good for you?
Will Spoelstra, who works at the Royal Botanic Gardens, says, “
Which plants can you grow?
Aloe vera, peace lilies and spider plants are some of the species that are easy to grow indoors. You can buy plants from supermarkets, garden centres or online. Younger plants are often cheaper than fully grown ones, and you get to care for them as they mature — which is part of the joy of owning plants. “
A.All plants are different |
B.Not only do they look beautiful |
C.There are many benefits to growing plants indoors |
D.Instead, they grow better inside, where it is warmer |
E.Plants like peace lilies and devil’s ivy are among the best |
F.Changing the pot of your plant from time to time will also help |
G.Learning about the requirements of each plant can be very rewarding |
2 . Animals can adapt quickly to survive unfavorable environmental conditions. Evidence is mounting to show that plants can, too. A paper published in the journal Trends in Plant Science details how plants are rapidly adapting to the effects of climate change, and how they are passing down these adaptations to their offspring(后代).
Plants are facing more environmental stresses than ever. For example, climate change is making winters shorter in many locations, and plants are responding. “Many plants require a minimum period of cold in order to set up their environmental clock to define their flowering time,” says Martinelli, a plant geneticist at the University of Florence. “As cold seasons shorten, plants have adapted to require shorter periods of cold to delay flowering. These mechanisms allow plants to avoid flowering in periods when they have fewer opportunities to reproduce.”
Because plants don’t have neural(神经的) networks, their memory is based entirely on cellular(细胞的),molecular(分子的),and biochemical networks. These networks make up what the researchers call somatic memory(体细胞记忆). “It allows plants to recognize the occurrence of a previous environmental condition and to react accordingly,” says Martinelli.
These somatic memories can then be passed to the plants’ offspring via epigenetics(表现遗传). “Several examples demonstrate the existence of molecular mechanisms modulating plant memory to environmental stresses and affecting the adaptation of offspring to these stresses,” says Martinelli.
Going forward, Martinelli hopes to understand even more about the genes that are being passed down. “We are particularly interested in decoding the epigenetic alphabet without changes in DNA sequence(序列),”he says. “This is especially important when we consider the rapid climate change, we observe today that every living organism, including plants, needs to quickly adapt to survive.”
1. What adaptations have plants made to shortened cold seasons?A.They have shortened their flowering time. |
B.They have got more chances to reproduce. |
C.They have avoided flowering in cold seasons. |
D.They have adjusted their environmental clock. |
A.It is entirely based on neural networks. |
B.It can help the plants’ offspring to survive. |
C.It can help relieve environmental stresses. |
D.It disturbs the plants’ biochemical networks. |
A.Adjusting. | B.Treasuring. |
C.Recording. | D.Sharing. |
A.Plants are smart about flowering time |
B.Plants can also adapt to climate change |
C.Environmental stresses challenge plants |
D.Mysteries of plant genes are to be unfolded |
3 . At first, the grains of rice that Ingo Potrykus held in his fingers did not seem at all
For more than a decade Potrykus had
At that point, he tackled an even greater challenge. The golden grains
The debate began the moment genetically engineered crops (GM crops) were first sold in the 1990s, and it has
The hostility is
The benefits did seem small
Many people
A.typical | B.special | C.local | D.white |
A.dreamed of | B.come in handy | C.been reminded of | D.broken up |
A.attempt at | B.effort to | C.resistance to | D.majority of |
A.But | B.And | C.While | D.Since |
A.surprise | B.obstacle | C.norm | D.opposition |
A.achieved | B.stressed | C.overlooked | D.contained |
A.was caught in | B.was alive with | C.be conscious of | D.was honored by |
A.announced | B.maintained | C.escalated | D.applied |
A.brilliant | B.understandable | C.discharged | D.rewarding |
A.introduced | B.reminded | C.respected | D.overlooked |
A.toss and turn | B.give and take | C.produce and sell | D.demand and supply |
A.until | B.after | C.although | D.when |
A.feature | B.mark | C.build | D.benefit |
A.worried about | B.ashamed of | C.filled with | D.admired for |
A.terror | B.misery | C.starvation | D.crisis |
4 . With no special equipment, no fences and no watering, two abandoned agricultural fields in the UK have been rewilded (重新野化), in large part due to the efforts of jays, which actually “engineered” these new woodlands. Researchers now hope that rewilding projects can take a more natural and hands-off approach and that jays can shed some of their bad reputations.
The two fields, which researchers have called the New Wilderness and the Old Wilderness, had been abandoned in 1996 and 1961 respectively. The former was a bare field, while the latter was grassland—both lay next to ancient woodlands. Researchers had suspected that the fields would gradually return to wilderness, but it was impressive to see just how quickly this happened, and how much of it was owed to birds.
Using aerial data, the researchers monitored the two sites. After just 24 years, the New Wilderness had grown into a young, healthy wood with 132 live trees per hectare, over half of which (57%) were oaks. Meanwhile, the Old Wilderness resembled a mature woodland after 39 years, with 390 trees per hectare.
“This native woodland restoration was approaching the structure (but not the species composition) of long-established woodlands within six decades,” the researchers explained in the study.
Part of this reforestation was done by the wind, and researchers suspect that previous ground disturbance may have aided the woodland establishment—which is good news, as it would suggest that agricultural areas may be reforested faster than anticipated. However, animals—Eurasian jays, thrushes, wood mice, and squirrels—also played an important role in helping the forests take shape. This handful of species provided much of the natural regeneration needed for the forest to develop. Jays, in particular, seem to have done a lot of heavy lifting.
1. What does the underlined word “shed” in Paragraph 1 refer to?A.Be opposed to. |
B.Be ashamed of. |
C.Get used to. |
D.Get rid of. |
A.The scale of the woodlands. |
B.The diversity of the fields. |
C.The rate of the changes. |
D.The frequency of the wilderness. |
A.The woodland restoration was approaching the structure of long-established ones. |
B.Much of the wilderness of the fields was owed to birds. |
C.Previous ground disturbance aided the woodland establishment. |
D.How quickly the fields returned to wilderness over time. |
A.The essential role of humans in the reforestation. |
B.The factors that contribute to the reforestation. |
C.The importance of woodland establishment. |
D.The threats faced by a handful of wild animals. |
5 . 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. |
6 . “A beautiful field of flowers can be a rather noisy place. It’s just that we can’t hear the sounds.” Scientists at Tel Aviv University have conducted a six-year experiment, proving that plants make noise in certain stressful situations.
Plants produce a high frequency (频率) clicking sound, and when short of water, or damaged, the clicks become far more regular. They also made different sounds, depending on whether they were thirsty or injured. “Each plant and each type of stress is related to a specific sound,” said Professor Lilach Hadany, who led the research study.
Focusing particularly on tomatoes, wheat and corn, the plants were placed in a soundproof (隔音的) room and recorded by microphones. Some plants were starved of water, others cut, and a control group was left undamaged. The researchers used an algorithm (算法) to separate the noises, successfully telling the difference between the sounds depending on whether they were dry or cut. The algorithm did this in a greenhouse setting which included far more surrounding sounds, but it was still able to recognize the particular cries for help of the plants.
On average, the human ear can hear sounds up to around 20kHz, while the sounds produced by plants are in the 40-80kHz region, far beyond our hearing. “The sounds made by plants can’t be heard by humans but can probably be heard by various animals, such as bats, mice and insects,” Hadany tells us. Though this has yet to be proven, it’s possible that these creatures use this information to choose which plants to eat.
A study led by Reda Hassanien of China Agricultural University in Beijing years ago, also proved that plants reacted to sound waves, with some plants greatly increasing their yield. While evidence shows that plants can react to sounds, there’s no evidence today that they can actually hear them.
1. What can we know from the six-year experiment?A.Plants of different types make the sound of the same frequency. |
B.Plants produce more regular sound in certain stressful situations. |
C.Plants make sounds with a much lower frequency when stressed. |
D.Plants make the sound of the same frequency whatever the situation. |
A.To record the sounds. | B.To control the sounds. |
C.To produce the sounds. | D.To identify the sounds. |
A.Plants can hear each other’s cry for help. |
B.Animals can hear the sounds made by plants. |
C.Plants can make sounds and respond to sound waves. |
D.Animals decide what to eat based on the sounds plants make. |
A.Sounds That We Can’t Hear |
B.Beautiful Songs from Plants |
C.Plants React to Different Types of Stress |
D.Plants Talk, Especially When Stressed |
7 . Some of the oldest living things on our remarkable planet are trees. The record holders are bristlecone pines (狐尾松) of the western United States, quite a few of which are known to be more than 3,000 years old. One individual, discovered in 2012, is estimated to be more than 5,060 years old, making it the oldest known non-clonal tree in the world!
So, how do trees survive for thousands of years?
The other part of the answer has to do with how trees age. In fact, there is quite a debate about whether ancient trees can be considered “immortal (永生的)”. That is, will such trees ever die if they are not killed by an outside force? We may never know the answer to that, but, at the very least,
Older trees benefit greatly from having bodies made mostly of dead woody tissue. In fact, an old tree might be as much as 95 percent dead tissue! Given that it isn’t alive, wood does not require metabolic (新陈代谢的) activity to maintain it,
A.so an old tree doesn’t really need to do much to keep living |
B.This is a question that has something to do with the good luck of trees |
C.However, bristlecones are certainly not alone in terms of the oldest creatures |
D.This is a fascinating question for biologists that does not yet have a settled answer |
E.What’s more, some ancient trees have superior chemical defenses against pests and diseases |
F.which means that trees can survive everywhere without being limited by external and internal conditions |
G.we know that ancient trees age in ways that are dramatically different from the ways that most animals and even other plants age |
8 . Seagrass meadows(海草床) are wonder plants growing beneath the sea. They feed and shelter sea life and are masterful at storing carbon. Thanks to the assistance of tiger sharks, a huge seagrass meadow in the Bahamas Banks was recently discovered, offering the world a tool to fight climate change.
Seagrass has usually been detected by Earth-orbiting satellites that identify darker patches in the blue water. In this study, tiger sharks were selected as research tools due to their highly consistent associations with seagrass ecosystems. They spend 70% of their time in seagrass meadows. The team equipped eight tiger sharks with satellite tags (电子跟踪器), seven sharks with camera tags, and used a 360-degree camera on a shark for the first time ever.
The data researchers collected was astonishing. The world’s largest seagrass ecosystem, measuring at least 66,900 square kilometers, has been discovered. This reflects a 41% increase from previous estimates of global seagrass. Seagrass can capture (捕获) huge quantities of carbon by photosynthesis (光合作用) and stores it on the seafloor. In terms of climate change, this is excellent news; seagrass is 35 times faster a removing carbon than tropical rainforests. When referred to global seagrass carbon stock estimates, the study indicates that seagrass in the Bahamas may contain 19.2% to 26.3% of all the carbon stored in seagrass meadows on Earth.
Yet seagrass meadows are rapidly disappearing, with over 92% of meadows in the UK gone, according to the World Wildlife Fund. Scientists are collecting seeds and trying to grow new seagrass meadows through restoration projects. This new discovery offers optimism and proves the importance of the ocean for healing.
The sharks led us to the seagrass ecosystem in the Bahamas, which we now know is likely the most significant blue carbon sink(蓝色碳汇) on the planet. What this discovery shows us is that ocean exploration and research are essential for a healthy future. The untapped potential of the ocean is limitless. These meadows can be protected and can be replicated (复制,仿制), offering hope for climate change around the globe.
1. Why were tiger sharks chosen as research tools?A.They are more flexible than other sea animals. |
B.They can quickly adjust themselves to the deep sea. |
C.They have a strong connection with seagrass ecosystems. |
D.They can be easily equipped with experimental devices. |
A.The decline of global seagrass meadows. |
B.The impact of climate change on sea life. |
C.The rapid increase in the amount of carbon on Earth. |
D.The potential value of the world’s largest seagrass ecosystem. |
A.Planting more seagrass meadows. |
B.Developing new technology to collect seeds. |
C.Mapping the distribution of seagrass meadows. |
D.Encouraging people to join in restoration projects. |
A.The New Way of Removing Carbon |
B.The Significance of Ocean Exploration |
C.A New Discovery: World’s Largest Seagrass Meadow |
D.Tiger Sharks: Scientists’ Essential Helper to Study Climate |
9 . What if someone told you about a kind of grass as tall as the tallest trees? A grass as strong as steel? Would you believe that person? You should, for that grass is bamboo (竹子), which has more than 1,000 uses. It is not just a material for making useful products. Young bamboo is eaten, often mixed with other vegetables.
Bamboo grows in many parts of the world. In the USA it grows in many states like Virginia and Florida. Most bamboo, however, is found in wet and warm climates, especially in Asia and on the islands of the South Pacific Ocean.
In most Asian countries, bamboo is nearly as important as rice. This unusual material is used to not only build large buildings but also make water pipes, musical instruments and paper. There are over 1,000 kinds of bamboo. No wonder the lives of nearly half the people on earth would change greatly if there were no longer any bamboo.
1. According to the text, bamboo is actually a kind of .A.grass | B.steel | C.tree | D.vegetable |
A.Only in Asia. | B.Only in the USA. |
C.In wet and warm climates. | D.All over the world. |
A.Build large buildings. | B.Make water pipes. |
C.Make musical instruments and paper. | D.All of the above. |
A.Over 1,000. | B.Over 800. | C.Over 600. | D.Over 400. |
10 . On the streets of Manhattan and Washington, D. C., in neighborhoods in Seoul and parks in Paris, ginkgo (银杏) trees are losing their leaves in reaction to the first gust of cold winter air. This leaf drop, gradual at first, and then sudden, carpets streets with golden, fan-shaped leaves. Scientists are documenting evidence of the event happening later and later, a possible indication of climate change. But the story of ginkgos is not the familiar one of human carelessness with nature.
Thanks to fossils found in North Dakota, scientists found a ginkgo has genetically similar ancestors dating back 170 million years to the Jurassic Period. “It almost went extinct. Then humans rescued it and spread it around the world. It’s such a great evolutionary (进化) and cultural story,” says Peter Crane, a ginkgo expert.
One theory for the decline of the ginkgo species began 130 million years ago, when flowering plants began spreading. They grew faster and attracted more pollinators (传粉者) than ginkgos. “It’s possible that ginkgos were elbowed out of the way,” says Crane. Already competing to survive, ginkgos began to disappear during a time of global cooling that began around 66 million years ago. By the time the last ice age ended 11,000 years ago, the remaining survivors were found in China.
Ginkgo trees are smelly. “My guess is that they were eaten by animals that liked smelly things. They then passed through their body and grew.” Crane says. Those same seeds may have helped ginkgo find favor with humans 1,000 years ago. Once cleaned of their outer layer, ginkgo seeds are safe to eat. It’s then, when the trees had long since disappeared elsewhere, that people in China may have begun planting them and eating their seeds. Then gradually ginkgos spread across the world. Now it’s seemingly naturally resistant to insects and high levels of air pollution.
Crane isn’t worried about its future, though: The popularity of the species will help it survive. “Though its status in the wild may be difficult to access, it’s a plant that’s unlikely to ever go extinct,” he says.
1. What may have caused the further delay of ginkgo’s leaf drop?A.The colder weather in winter. |
B.The protection from city councils. |
C.The global warming phenomenon. |
D.The careless interaction with humans. |
A.The reasons why ginkgos almost died out. |
B.The advantages of ginkgos over other plants. |
C.The theories of experts for multiplying ginkgos. |
D.The competition between various flowering plants. |
A.Their eatable seeds. | B.Their unpleasant smell. |
C.The natural evolution. | D.The careful planting. |
A.Worried. | B.Optimistic. | C.Uncertain. | D.Hopeless. |