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  • By 2050, there are going to be

  • almost 10 billion of us living on this planet.

  • And all of us will need food to survive.

  • If we don't change anything and we will go on

  • in the way we are now consuming our food,

  • then the next 40 years,

  • we need to produce as much food as we did

  • over the last 8,000 years.

  • And that's a huge challenge.

  • Agriculture is the largest source

  • of non-CO2 greenhouse gas emissions.

  • And, along with climate change and urbanization,

  • the resources that we need to feed everyone,

  • things like space and water,

  • are becoming harder to find.

  • That's why scientists and farmers across the world

  • are finding new ways to help us and our planet thrive.

  • So you're now in the central area

  • of the Netherlands.

  • And within this area we have many different institutes

  • and industries that are focusing

  • on the big challenges in food.

  • We like to study things in nature,

  • try to learn from things in nature,

  • and try to transfer this into solutions

  • that can improve the quality of life of humankind.

  • Wageningen University is known

  • as the Silicon Valley of agriculture.

  • Students and researchers from more than 100 countries

  • work here in vast greenhouses and labs

  • to determine the future of our food and how we'll grow it.

  • The Green Revolution in the 20th century

  • started by a guy named Borlaug

  • and he was a plant breeder.

  • And what I like about the story

  • is that the guy got the Nobel Prize for Peace.

  • Not for science, but for peace.

  • And the reason was that he came up

  • with new cultivars of wheat

  • that were able to produce more per plant.

  • And, in that way, he could offer a solution

  • for the hunger that was quite important

  • at that time in Asia and in Africa.

  • The bad thing was, of course, that these new cultivars

  • also needed a lot of fertilizers,

  • a lot of pesticides.

  • And that's the reason why I think that we need

  • a new Green Revolution.

  • We need to produce more per square meter,

  • but at the same time

  • we need to use less fertilizer, less energy, less water.

  • So, more with less and better

  • is really a summary of our research programs.

  • Along with the driverless tractors

  • and agroforestry being developed here

  • at the university's research farm,

  • the next Green Revolution could rely on optimizing

  • the most fundamental process in every plant, photosynthesis.

  • All life depends, now, on photosynthesis.

  • So, it's an essential building block of life.

  • For a long time,

  • people thought this could not be changed anymore.

  • They thought this is a fixed thing.

  • It already exist for about 2 billion years,

  • so very long time,

  • and people thought the evolution

  • would have taken care of this.

  • And now it looks like it's not.

  • The team created a robot filled with cameras

  • that can image plants while they photosynthesize

  • using a property called chlorophyll fluorescence.

  • By examining photosynthesis at the DNA level,

  • they identified natural genetic variations

  • in the way plants handle light.

  • That data can be used to breed crops

  • which are almost 50% better at the process.

  • Not only could that double yields,

  • but the optimized plants will be more efficient

  • with resources like water and nutrients in the soil.

  • So, what the Green Revolution taught us

  • how by changing the architecture of plants,

  • we could harvest more of the plant

  • and that's probably saved humanity from a lot of trouble.

  • Now, this new step in looking at photosynthesis

  • could mean the same.

  • So, if we can improve

  • with only a few percentages photosynthesis,

  • we would also be able to improve plant productivity.

  • And if you can do that in a sustainable and durable way

  • for a long time and making it available to a lot of people,

  • by just increasing one trait,

  • then would give us a tremendous boost forwards.

  • On the other side of the world in China,

  • improving food production to feed its 1.4 billion people

  • is already an urgent problem.

  • This small-scale peasant economy

  • means lower production at a higher cost.

  • And, combined with food safety

  • and sustainability challenges, this creates major problems

  • for the country's agriculture industry.

  • Dr. Li Shaohua is the research director

  • at Sanan Sino-Science, a joint venture between

  • the Chinese Academy of Science and a local LED maker.

  • In 2016, they built this factory

  • made up of eight three-story buildings

  • to grow medicinal plants and vegetables.

  • This one building covers just under an acre of land

  • but provides 1.8 tons of produce every single day.

  • Their secret?

  • A modular planting system

  • made up of one-meter square boards

  • which contain lighting and storage for a nutrient solution.

  • The boards easily slot together

  • and can be replaced quickly if they break.

  • There's no need for pesticides

  • and the cooling system recycles evaporated water

  • back to the plants

  • so that some use over 18 times less

  • than if they were grown in a field.

  • For now, most of the vegetables are sold

  • to local supermarkets across Fujian Province

  • and one bag of lettuce costs 11 times more

  • than others on the shelf.

  • But the price is likely to get lower

  • as the technology becomes more widespread.

  • Solving problems in food production

  • will also mean that you are working on solving issues

  • that affects the whole Earth.

  • It's a combination of feeling responsible

  • for the environment

  • and feeling responsible for feeding the growing population.

By 2050, there are going to be

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B1 中級

如何養活100億人 (How To Feed 10 Billion People)

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    林宜悉 發佈於 2021 年 01 月 14 日
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