fusion fuel

简明释义

聚变燃料

英英释义

例句

1.The development of fusion fuel 聚变燃料 could lead to a sustainable energy future.

开发fusion fuel 聚变燃料可能会导致可持续的能源未来。

2.Researchers are exploring the efficiency of different fusion fuels 聚变燃料 in laboratory experiments.

研究人员正在实验室实验中探索不同fusion fuels 聚变燃料的效率。

3.The ITER project aims to demonstrate the feasibility of fusion fuel 聚变燃料 as a viable energy source.

国际热核聚变实验堆（ITER）项目旨在证明fusion fuel 聚变燃料作为可行能源的可行性。

4.Using fusion fuel 聚变燃料 can potentially reduce our reliance on fossil fuels.

使用fusion fuel 聚变燃料可以潜在地减少我们对化石燃料的依赖。

5.Scientists are researching new types of fusion fuel 聚变燃料 to improve energy production.

科学家们正在研究新型的fusion fuel 聚变燃料以提高能源生产。

作文

The concept of fusion fuel is one that has captured the imagination of scientists and researchers for decades. Unlike conventional fuels that rely on combustion, fusion fuel refers to the materials used in nuclear fusion processes, which have the potential to provide a nearly limitless source of energy. The most commonly discussed fusion fuel is isotopes of hydrogen, specifically deuterium and tritium. These isotopes can be combined under extreme temperatures and pressures to release vast amounts of energy, mimicking the processes that power the sun. One of the significant advantages of fusion fuel is its abundance. Deuterium can be extracted from seawater, and tritium can be bred from lithium, which is also relatively abundant. This contrasts sharply with fossil fuels, which are finite and contribute to environmental degradation through their extraction and use. The potential for fusion fuel to provide a clean, sustainable energy source is one of the primary reasons why many countries are investing heavily in fusion research.Moreover, fusion fuel produces minimal radioactive waste compared to traditional nuclear fission reactors. The waste generated from fusion reactions is significantly less hazardous and has a much shorter half-life, meaning it poses a reduced risk to the environment and human health over time. This characteristic makes fusion fuel an attractive option for future energy generation, as society grapples with the challenges of climate change and energy security.Despite the promising benefits of fusion fuel, there are still substantial technical challenges that need to be overcome before fusion can become a practical energy source. Achieving and maintaining the extreme conditions necessary for fusion to occur is a complex task. Current experimental reactors, such as ITER in France, are working towards achieving a net positive energy output from fusion reactions, but this goal has yet to be realized. Researchers are exploring various approaches to make fusion more feasible, including magnetic confinement and inertial confinement techniques.In conclusion, the pursuit of fusion fuel represents a critical frontier in the quest for sustainable energy solutions. While significant hurdles remain, the potential rewards of harnessing fusion fuel could transform our energy landscape, offering a cleaner, safer, and virtually limitless source of power. As we continue to innovate and push the boundaries of science, the dream of utilizing fusion fuel may one day become a reality, providing humanity with the energy needed to thrive without compromising the health of our planet.

“聚变燃料”的概念吸引了科学家和研究人员的想象力，已经有几十年之久。与依赖燃烧的传统燃料不同，聚变燃料是指在核聚变过程中使用的材料，这些材料有潜力提供几乎无限的能源。最常讨论的聚变燃料是氢的同位素，特别是氘和氚。这些同位素可以在极端温度和压力下结合，释放出大量的能量，模仿太阳的动力过程。聚变燃料的一个显著优点是其丰富性。氘可以从海水中提取，而氚可以从锂中繁殖，而锂也相对丰富。这与化石燃料形成鲜明对比，后者是有限的，并且由于其开采和使用而对环境造成破坏。聚变燃料能够提供一种清洁、可持续的能源来源，是许多国家在聚变研究上投入大量资金的主要原因之一。此外，聚变燃料相比于传统的核裂变反应堆产生的放射性废物要少得多。这种聚变反应产生的废物的危害性显著较低，半衰期也短，这意味着它对环境和人类健康的风险随时间减少。这一特性使得聚变燃料成为未来能源生成的一个有吸引力的选择，因为社会正在应对气候变化和能源安全的挑战。尽管聚变燃料有着令人鼓舞的好处，但在聚变成为实际能源来源之前，仍然存在着重大的技术挑战。实现并维持聚变发生所需的极端条件是一项复杂的任务。目前的实验反应堆，如法国的ITER，正在努力实现聚变反应的净正能量输出，但这一目标尚未实现。研究人员正在探索各种方法，使聚变更具可行性，包括磁约束和惯性约束技术。总之，追求聚变燃料代表了可持续能源解决方案探索中的一个关键前沿。尽管仍然存在重大障碍，但利用聚变燃料的潜在回报可能会改变我们的能源格局，提供一种更清洁、更安全、几乎无限的电源。随着我们继续创新并推动科学的边界，利用聚变燃料的梦想有一天可能会成为现实，为人类提供所需的能源，使其在不损害地球健康的情况下蓬勃发展。