fusion reaction

简明释义

热核反应

英英释义

例句

1.In a fusion reaction 聚变反应, the nuclei of two light atoms combine to form a heavier nucleus.

在fusion reaction 聚变反应中，两个轻原子的原子核结合形成一个更重的原子核。

2.A successful fusion reaction 聚变反应 could provide nearly limitless energy with minimal environmental impact.

成功的fusion reaction 聚变反应可以提供几乎无限的能源，并对环境影响最小。

3.The sun generates energy through a continuous fusion reaction 聚变反应 that converts hydrogen into helium.

太阳通过持续的fusion reaction 聚变反应将氢转化为氦来产生能量。

4.Scientists are researching how to achieve a stable fusion reaction 聚变反应 for sustainable energy production.

科学家们正在研究如何实现稳定的fusion reaction 聚变反应以实现可持续能源生产。

5.The ITER project aims to create the world's largest experimental reactor to study fusion reactions 聚变反应.

国际热核聚变实验堆（ITER）项目旨在创建世界上最大的实验反应堆，以研究fusion reactions 聚变反应。

作文

The concept of a fusion reaction is one of the most fascinating and promising areas of research in modern physics. A fusion reaction occurs when two light atomic nuclei combine to form a heavier nucleus, releasing a significant amount of energy in the process. This process is the same that powers the sun and other stars, where hydrogen nuclei fuse to create helium, releasing energy that sustains life on Earth. Understanding fusion reactions could revolutionize our approach to energy production, offering a cleaner and virtually limitless source of power compared to traditional fossil fuels.In recent years, scientists have made considerable advancements in harnessing fusion reactions for practical use. The primary challenge has been achieving the conditions necessary for these reactions to occur, which typically require extremely high temperatures and pressures. Researchers are exploring various methods, such as magnetic confinement and inertial confinement, to maintain the necessary conditions for a sustained fusion reaction. Projects like ITER (International Thermonuclear Experimental Reactor) in France aim to demonstrate the feasibility of nuclear fusion as a large-scale and carbon-free source of energy.The potential benefits of successful fusion reactions are immense. Unlike nuclear fission, which splits heavy atoms and produces long-lived radioactive waste, fusion reactions primarily use isotopes of hydrogen—deuterium and tritium—as fuel. These isotopes are abundant and can be extracted from seawater and lithium. Moreover, the byproducts of fusion reactions are generally less harmful, resulting in minimal environmental impact.Despite the challenges, the scientific community remains optimistic about the future of fusion reactions. If we can achieve a net positive energy output from fusion reactions, it could lead to a new era of energy independence and sustainability. Countries around the world are investing in research and development to unlock the secrets of fusion reactions, hoping to create a cleaner, safer, and more sustainable energy future.In conclusion, the study of fusion reactions holds great promise for addressing some of the most pressing energy challenges of our time. As we continue to explore this incredible phenomenon, we move closer to realizing the dream of harnessing the power of the stars for our energy needs. The journey toward practical fusion reactions may be long and complex, but the potential rewards make it a pursuit worth undertaking. With continued dedication and innovation, we may one day see fusion reactions become a cornerstone of global energy production, fundamentally changing the way we power our world.

‘聚变反应’的概念是现代物理学中最迷人和最有前景的研究领域之一。‘聚变反应’发生在两个轻原子核结合形成一个更重的原子核的过程中，在这一过程中释放出大量能量。这一过程与太阳和其他恒星的能量来源相同，氢核聚合成氦，释放出维持地球生命的能量。理解‘聚变反应’可能会彻底改变我们对能源生产的看法，提供一种比传统化石燃料更清洁和几乎无限的能源来源。近年来，科学家在利用‘聚变反应’进行实际应用方面取得了显著进展。主要挑战是实现这些反应发生所需的条件，通常需要极高的温度和压力。研究人员正在探索多种方法，例如磁约束和惯性约束，以维持持续‘聚变反应’所需的条件。法国的ITER（国际热核聚变实验堆）等项目旨在展示核聚变作为大规模和无碳能源来源的可行性。成功的‘聚变反应’潜在好处巨大。与核裂变不同，核裂变是分裂重原子并产生长期放射性废物，‘聚变反应’主要使用氢的同位素——氘和氚作为燃料。这些同位素丰富，可以从海水和锂中提取。此外，‘聚变反应’的副产品通常危害较小，导致环境影响最小。尽管面临挑战，科学界对‘聚变反应’的未来仍然持乐观态度。如果我们能够实现‘聚变反应’的净正能量输出，这可能会导致能源独立和可持续发展的新时代。世界各国正在投资研究和开发，以解锁‘聚变反应’的秘密，希望创造一个更清洁、更安全、更可持续的能源未来。总之，‘聚变反应’的研究为解决我们时代一些最紧迫的能源挑战提供了巨大希望。随着我们继续探索这一令人难以置信的现象，我们将更接近实现利用星星的力量满足我们的能源需求的梦想。实现实际的‘聚变反应’的旅程可能漫长而复杂，但潜在的回报使其成为值得追求的事业。随着持续的奉献和创新，我们或许有一天会看到‘聚变反应’成为全球能源生产的基石，从根本上改变我们为世界供电的方式。