The Green Machine: How Photosynthesis Sustains Life on Earth: Đề thi IELTS READING (Actual test)

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II. The Green Machine: How Photosynthesis Sustains Life on Earth: Đề thi IELTS READING (Actual test)

"The Green Machine: How Photosynthesis Sustains Life on Earth"

Photosynthesis is an intricate biochemical process that serves as the cornerstone for life on Earth, sustaining ecosystems and regulating atmospheric conditions. At its core, photosynthesis enables plants, algae, and certain bacteria to convert light energy into chemical energy, using carbon dioxide and water as primary raw materials. This conversion not only fuels the growth of autotrophs but also provides the energy foundation for virtually all living organisms. Understanding photosynthesis is crucial for advancing fields such as agriculture, environmental science, and climate change mitigation, as its efficiency directly impacts food security, biodiversity, and carbon sequestration.

The process of photosynthesis can be categorized into two main stages: the light-dependent reactions and the light-independent reactions, often referred to as the Calvin cycle. The former occurs in the thylakoid membranes of chloroplasts, where chlorophyll absorbs photons from sunlight, initiating a chain of events that result in the production of adenosine triphosphate (ATP) and nicotinamide adenine dinucleotide phosphate (NADPH). These molecules store energy, which is later used in the second stage, the Calvin cycle, to convert atmospheric carbon dioxide into glucose.

The efficiency of photosynthesis is influenced by several factors, including light intensity, temperature, and the availability of carbon dioxide. The relationship between light intensity and the rate of photosynthesis follows a hyperbolic pattern, with an increase in light intensity leading to a proportional increase in the rate of photosynthesis, until a saturation point is reached. Beyond this point, other factors, such as enzyme activity and carbon dioxide concentration, become limiting. Temperature also plays a crucial role, as photosynthesis is dependent on enzymatic processes, which operate optimally within specific temperature ranges. Excessive heat can denature these enzymes, reducing photosynthetic efficiency, while low temperatures can slow down biochemical processes.>> Form đăng kí giải đề thi thật IELTS 4 kĩ năng kèm bài giải bộ đề 100 đề PART 2 IELTS SPEAKING quý đang thi (update hàng tuần) từ IELTS TUTOR

However, photosynthesis is not a process without its limitations and inefficiencies. One of the primary inefficiencies lies in the conversion of light energy into chemical energy. In natural conditions, only a small fraction of the sunlight that reaches a plant's surface is absorbed and utilized in photosynthesis. The majority is either reflected or transmitted through the plant. Furthermore, the process of photorespiration, which occurs when the enzyme RuBisCO erroneously fixes oxygen instead of carbon dioxide, represents another inefficiency. Photorespiration leads to the loss of carbon and energy, reducing the overall productivity of photosynthesis. This phenomenon is particularly problematic in C3 plants, which are the most common type of plants on Earth, as their Calvin cycle is more susceptible to the detrimental effects of oxygen interference.

Advancements in genetic engineering and biotechnological research offer promising solutions to mitigate these inefficiencies. For instance, scientists are exploring the possibility of enhancing the RuBisCO enzyme’s specificity for carbon dioxide, thus reducing photorespiration and increasing photosynthetic efficiency. Another promising avenue is the introduction of genes from C4 or CAM (Crassulacean Acid Metabolism) pathways, which are more efficient in carbon fixation under hot and dry conditions. These pathways have evolved in certain plant species as adaptations to arid environments and could be integrated into staple crops to enhance agricultural productivity in the face of climate change.

Beyond its biological significance, photosynthesis plays a crucial role in regulating the Earth's atmosphere and climate. The process is responsible for the sequestration of carbon dioxide, a greenhouse gas, from the atmosphere. As plants absorb carbon dioxide for photosynthesis, they help mitigate the effects of global warming by reducing the overall concentration of this gas. Forests, grasslands, and oceans, which act as massive carbon sinks, play an essential role in maintaining the balance of atmospheric gases. However, deforestation, pollution, and land-use changes have diminished the Earth’s ability to absorb carbon, exacerbating the ongoing climate crisis.

In conclusion, photosynthesis is not merely a biological process but a vital mechanism that sustains life on Earth and contributes to the global regulation of atmospheric gases. Its efficiency, while remarkable, is not without its challenges, and addressing these inefficiencies presents both scientific and agricultural opportunities. As humanity grapples with issues like food security, environmental degradation, and climate change, harnessing the power of photosynthesis through biotechnological innovations holds the key to sustainable solutions for the future. Understanding and optimizing photosynthesis will not only enhance crop yields but also provide a critical tool in our collective efforts to combat environmental challenges and ensure the resilience of ecosystems worldwide.

Read the passage below carefully. For each statement, choose "True," "False," or "Not Given" based on the information provided in the passage.

  1. Photosynthesis is a simple biochemical process that is not essential for life on Earth.
    FALSE – Photosynthesis is an intricate and essential biochemical process for life on Earth.

  2. Plants, algae, and certain bacteria are capable of performing photosynthesis.
    TRUE – Plants, algae, and certain bacteria are capable of performing photosynthesis.

  3. The main purpose of photosynthesis is to convert light energy into chemical energy.
    TRUE – The main purpose of photosynthesis is to convert light energy into chemical energy.

  4. The Calvin cycle occurs in the thylakoid membranes of chloroplasts.
    FALSE – The Calvin cycle occurs in the stroma of chloroplasts, not the thylakoid membranes.

  5. ATP and NADPH are produced during the light-dependent reactions.
    TRUE – ATP and NADPH are produced during the light-dependent reactions.

  6. Light intensity has no effect on the rate of photosynthesis.
    FALSE – Light intensity does affect the rate of photosynthesis.

  7. As light intensity increases, the rate of photosynthesis increases until a saturation point is reached.
    TRUE – As light intensity increases, the rate of photosynthesis increases until a saturation point is reached.

  8. High temperatures always improve photosynthesis by speeding up enzymatic activity.
    FALSE – High temperatures can accelerate enzymatic activity up to an optimal level, but beyond this point, they can impair the process.

  9. If carbon dioxide is not available, photosynthesis will still proceed efficiently.
    FALSE – Without carbon dioxide, photosynthesis will not proceed efficiently.

  10. Photorespiration occurs when RuBisCO fixes oxygen instead of carbon dioxide.
    TRUE – Photorespiration occurs when RuBisCO fixes oxygen instead of carbon dioxide.

  11. C3 plants are less efficient than C4 plants, especially in conditions where photorespiration is a concern.
    TRUE – C3 plants are less efficient than C4 plants, especially in conditions where photorespiration is a concern.

  12. Genetic engineering can potentially reduce photorespiration in plants.
    TRUE – Genetic engineering can potentially reduce photorespiration in plants.

  13. C4 and CAM pathways are more efficient at carbon fixation under certain conditions compared to C3 pathways.>> IELTS TUTOR có hướng dẫn kĩ PHÂN TÍCH ĐỀ THI THẬT TASK 2 (dạng advantages & disadvantages) NGÀY 04/8/2020 IELTS WRITING GENERAL MÁY TÍNH (kèm bài được sửa hs đi thi)
    TRUE – C4 and CAM pathways are more efficient at carbon fixation compared to C3 pathways.

  14. An increase in atmospheric carbon dioxide generally reduces the rate of photosynthesis.
    FALSE – An increase in atmospheric carbon dioxide generally increases the rate of photosynthesis.

  15. The process of photosynthesis helps to regulate the Earth’s atmospheric conditions.
    TRUE – Photosynthesis plays a crucial role in regulating the Earth’s atmospheric conditions by sequestering carbon dioxide.

  16. The majority of sunlight that reaches plants is absorbed and used for photosynthesis.
    FALSE – The majority of sunlight is either reflected or transmitted through the plant, not absorbed.

  17. Photorespiration decreases the overall productivity of photosynthesis.
    TRUE – Photorespiration decreases the overall productivity of photosynthesis.

  18. Biotechnological advancements could increase photosynthetic efficiency.
    TRUE – Biotechnological advancements could increase photosynthetic efficiency.

  19. Photosynthesis contributes to the sequestration of carbon dioxide in the atmosphere.
    TRUE – Photosynthesis contributes to the sequestration of carbon dioxide in the atmosphere.

  20. Deforestation and pollution have improved the Earth’s ability to absorb carbon dioxide.
    FALSE – Deforestation and pollution have diminished the Earth’s ability to absorb carbon dioxide.

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