fusion technology

简明释义

聚变技术

英英释义

例句

1.Scientists are collaborating internationally to improve fusion technology 聚变技术 for commercial use.

科学家们正在国际间合作，以改进聚变技术 fusion technology以供商业使用。

2.The success of fusion technology 聚变技术 could revolutionize how we generate electricity.

聚变技术 fusion technology的成功可能会彻底改变我们发电的方式。

3.The ITER project is a major international effort to develop fusion technology 聚变技术 in France.

ITER项目是一个在法国开发聚变技术 fusion technology的重大国际努力。

4.The latest advancements in fusion technology 聚变技术 promise to provide a nearly limitless source of energy.

最新的聚变技术 fusion technology进展承诺提供几乎无限的能源来源。

5.Many governments are investing heavily in research for fusion technology 聚变技术 to combat climate change.

许多政府正在大力投资于聚变技术 fusion technology的研究，以应对气候变化。

作文

In recent years, the term fusion technology has gained significant attention in both scientific and public discourse. This technology refers to the process of combining two lighter atomic nuclei to form a heavier nucleus, a reaction that releases a tremendous amount of energy. The most well-known example of fusion technology is the nuclear fusion that powers the sun, providing an almost limitless source of energy. Unlike nuclear fission, which splits heavy atomic nuclei and can produce hazardous waste, fusion technology promises a cleaner and safer alternative for energy production.The potential benefits of fusion technology are immense. First and foremost, it offers a solution to the world's growing energy demands. As fossil fuel reserves dwindle and climate change becomes an increasingly pressing issue, the need for sustainable and renewable energy sources has never been more critical. Fusion technology could provide a nearly inexhaustible supply of energy, as the primary fuel, isotopes of hydrogen like deuterium and tritium, can be extracted from water and lithium, both of which are abundant on Earth.Moreover, fusion technology produces minimal environmental impact. The by-products of fusion reactions are primarily helium, a harmless gas, and the energy produced can be harnessed without the harmful emissions associated with burning fossil fuels. This makes fusion technology an attractive option in the fight against climate change. Additionally, since the risk of catastrophic failure is significantly lower than that of fission reactors, fusion technology could provide a safer alternative for energy generation.However, despite its promise, the development of fusion technology faces several challenges. Achieving the necessary conditions for fusion—extremely high temperatures and pressures—requires advanced engineering and significant investment. Currently, research facilities like ITER (International Thermonuclear Experimental Reactor) in France are working tirelessly to make fusion technology a viable energy source. The goal of ITER is to demonstrate the feasibility of fusion as a large-scale and carbon-free source of energy, paving the way for future commercial fusion reactors.Furthermore, there are still scientific hurdles to overcome. The process of confining the hot plasma where fusion occurs is complex and requires innovative solutions. Scientists are exploring various confinement methods, including magnetic confinement and inertial confinement, to achieve stable and sustained fusion reactions. The success of these experiments will determine the timeline for the practical application of fusion technology.In conclusion, fusion technology represents a revolutionary advancement in the quest for sustainable energy. With its potential to provide clean, safe, and abundant energy, it could play a crucial role in addressing global energy challenges and combating climate change. While the road to successful implementation is fraught with challenges, ongoing research and international collaboration hold the promise of making fusion technology a reality in the near future. As we continue to invest in and explore this groundbreaking field, the hope is to unlock the power of the stars and provide a brighter, more sustainable future for generations to come.

近年来，术语聚变技术在科学和公众话语中引起了显著关注。这项技术指的是将两个较轻的原子核结合形成一个较重的原子核的过程，这一反应释放出巨大的能量。最著名的聚变技术例子是为太阳提供能量的核聚变，它几乎提供了无限的能源。与裂变不同，裂变是分裂重原子核并可能产生有害废物，聚变技术承诺为能源生产提供更清洁和更安全的替代方案。聚变技术的潜在好处是巨大的。首先，它为世界日益增长的能源需求提供了解决方案。随着化石燃料储备的减少以及气候变化日益紧迫，寻找可持续和可再生能源的需求比以往任何时候都要重要。聚变技术可以提供几乎取之不尽的能源，因为主要燃料氢的同位素如氘和氚可以从水和锂中提取，而这两者在地球上都很丰富。此外，聚变技术对环境的影响极小。聚变反应的副产品主要是氦，一种无害的气体，所产生的能量可以在没有与燃烧化石燃料相关的有害排放的情况下利用。这使得聚变技术在应对气候变化的斗争中成为一个有吸引力的选择。此外，由于发生灾难性故障的风险明显低于裂变反应堆，聚变技术可以为能源生成提供更安全的替代方案。然而，尽管前景光明，聚变技术的发展仍面临若干挑战。实现聚变所需的条件——极高的温度和压力——需要先进的工程技术和大量投资。目前，像法国的国际热核聚变实验堆（ITER）这样的研究机构正在不懈努力，使聚变技术成为一种可行的能源来源。ITER的目标是证明聚变作为大规模和无碳能源的可行性，为未来商业聚变反应堆铺平道路。此外，仍然存在科学上的障碍。限制聚变发生的高温等离子体的过程复杂，需要创新的解决方案。科学家们正在探索各种约束方法，包括磁约束和惯性约束，以实现稳定的持续聚变反应。这些实验的成功将决定聚变技术的实际应用时间表。总之，聚变技术代表了可持续能源追求中的革命性进展。凭借其提供清洁、安全和丰富能源的潜力，它可能在应对全球能源挑战和抗击气候变化方面发挥关键作用。尽管成功实施的道路充满挑战，但持续的研究和国际合作为将聚变技术变为现实带来了希望。当我们继续投资和探索这一突破性领域时，希望能够解锁星星的力量，为未来几代人提供一个更加光明和可持续的未来。