nuclear fusion energy

简明释义

核聚变能量

英英释义

例句

1.The potential of nuclear fusion energy 核聚变能 could revolutionize the energy industry by providing nearly limitless power.

核聚变能 nuclear fusion energy的潜力可能会彻底改变能源行业，提供几乎无限的电力。

2.Unlike fossil fuels, nuclear fusion energy 核聚变能 produces minimal waste and no greenhouse gases.

与化石燃料不同，核聚变能 nuclear fusion energy产生的废物极少且不产生温室气体。

3.Many countries are investing in research facilities to develop nuclear fusion energy 核聚变能 technologies.

许多国家正在投资研究设施，以开发核聚变能 nuclear fusion energy技术。

4.The ITER project aims to demonstrate the feasibility of nuclear fusion energy 核聚变能 on a large scale.

国际热核聚变实验堆（ITER）项目旨在展示大规模核聚变能 nuclear fusion energy的可行性。

5.Scientists are researching ways to harness nuclear fusion energy 核聚变能 as a clean and sustainable power source.

科学家们正在研究如何利用核聚变能 nuclear fusion energy作为一种清洁和可持续的能源。

作文

Nuclear fusion energy, or 核聚变能, is a process that powers the sun and other stars. It occurs when two light atomic nuclei combine to form a heavier nucleus, releasing an immense amount of energy in the process. This energy is not only vital for the existence of stars, but it also holds the potential to revolutionize our energy systems on Earth. Unlike nuclear fission, which splits heavy atoms and produces radioactive waste, 核聚变能 promises a cleaner and more sustainable alternative. The primary fuel for nuclear fusion is isotopes of hydrogen, namely deuterium and tritium, which are abundant and can be extracted from seawater and lithium. The quest for harnessing 核聚变能 has been ongoing for decades, with significant advancements made in recent years. Research facilities like the ITER project in France aim to create a controlled environment where fusion reactions can occur sustainably. The challenges are immense, as achieving the necessary conditions for fusion—extremely high temperatures and pressures—requires cutting-edge technology and substantial investment. However, the potential benefits of successful fusion energy generation are staggering. First and foremost, 核聚变能 could provide a virtually limitless source of energy. With the world's growing energy demands and the urgent need to transition away from fossil fuels, fusion presents a viable solution. It could significantly reduce greenhouse gas emissions and help mitigate climate change. Additionally, fusion does not produce long-lived radioactive waste, making it a safer option compared to current nuclear power technologies. Moreover, the safety aspect of 核聚变能 is a critical advantage. Unlike fission reactors, which can experience catastrophic failures, fusion reactions are inherently safe. If a malfunction occurs, the reaction simply stops, eliminating the risk of explosions or meltdowns. This makes fusion a highly attractive option for future energy production. Despite these advantages, public perception and funding remain hurdles for the advancement of 核聚变能. Many people are still skeptical about nuclear energy in general due to historical accidents and the stigma surrounding them. Educating the public about the safety and environmental benefits of fusion is essential to garner support for research and development. Furthermore, governments and private sectors must invest in fusion technology to bring it to fruition. In conclusion, 核聚变能 represents a promising frontier in energy production. With its potential for clean, abundant, and safe energy, it could play a pivotal role in addressing the global energy crisis and combating climate change. As researchers continue to overcome the technical challenges associated with fusion, the dream of harnessing the same process that powers the stars may soon become a reality on Earth. Investing in 核聚变能 is not just a scientific endeavor; it is an investment in a sustainable future for generations to come.

核聚变能，即核聚变能，是为太阳和其他恒星提供能量的过程。当两个轻原子核结合形成一个更重的原子核时，就会释放出巨大的能量。这种能量不仅对恒星的存在至关重要，而且还具有在地球上彻底改变我们的能源系统的潜力。与裂变不同，裂变是将重原子分裂并产生放射性废物，而核聚变能则承诺提供一种更清洁、更可持续的替代方案。核聚变的主要燃料是氢的同位素，主要是氘和氚，这些元素丰富且可以从海水和锂中提取。对利用核聚变能的探索已经进行了数十年，近年来取得了显著进展。像法国的国际热核聚变实验反应堆（ITER）项目这样的研究机构旨在创造一个可以持续发生聚变反应的受控环境。面临的挑战是巨大的，因为实现聚变所需的条件（极高的温度和压力）需要尖端技术和大量投资。然而，成功生成聚变能量的潜在好处是惊人的。首先，核聚变能可以提供几乎无限的能源来源。随着世界能源需求的不断增长以及迫切需要摆脱化石燃料，聚变呈现出一种可行的解决方案。它可以显著减少温室气体排放，并帮助减缓气候变化。此外，聚变不会产生长期放射性废物，使其成为比当前核电技术更安全的选择。此外，核聚变能的安全性是一个关键优势。与可能发生灾难性故障的裂变反应堆不同，聚变反应本质上是安全的。如果发生故障，反应会自动停止，消除爆炸或熔毁的风险。这使得聚变成为未来能源生产的高度吸引人的选择。尽管有这些优势，公众认知和资金仍然是推动核聚变能发展的障碍。由于历史事故及其相关的污名，许多人对核能仍持怀疑态度。教育公众有关聚变的安全性和环境益处对于获得对研究和开发的支持至关重要。此外，各国政府和私营部门必须投资于聚变技术，以实现其愿景。总之，核聚变能代表了能源生产中一个充满希望的前沿。凭借其清洁、丰富和安全的能源潜力，它可能在解决全球能源危机和应对气候变化方面发挥关键作用。随着研究人员继续克服与聚变相关的技术挑战，利用与星星相同的过程的梦想可能很快就在地球上成为现实。投资于核聚变能不仅仅是科学事业；它是对可持续未来的投资，为后代着想。