fusion heat

简明释义

熔解热

英英释义

例句

1.Engineers are developing materials that can withstand the extreme conditions of fusion heat 聚变热 for future reactors.

工程师们正在开发能够承受未来反应堆中极端条件的材料，以抵御fusion heat 聚变热。

2.The immense temperatures created by fusion heat 聚变热 can be harnessed for advanced propulsion systems in space travel.

由fusion heat 聚变热产生的巨大温度可以用于太空旅行中的先进推进系统。

3.Scientists are studying how to contain fusion heat 聚变热 in order to achieve sustainable energy production.

科学家们正在研究如何控制fusion heat 聚变热以实现可持续能源生产。

4.The nuclear reactor operates by harnessing the energy produced from fusion heat 聚变热 to generate electricity.

核反应堆通过利用产生的fusion heat 聚变热来发电。

5.The research on fusion heat 聚变热 has led to breakthroughs in clean energy technology.

对fusion heat 聚变热的研究导致了清洁能源技术的突破。

作文

In the realm of physics and energy production, the term fusion heat refers to the immense amount of thermal energy released during nuclear fusion reactions. These reactions occur when two light atomic nuclei combine to form a heavier nucleus, releasing energy in the process. This phenomenon is not only fundamental to the understanding of stellar processes but also holds great potential for future energy solutions on Earth. The sun, for example, generates its energy through the fusion of hydrogen atoms into helium, producing the fusion heat that warms our planet and sustains life. The concept of fusion heat is particularly relevant in discussions about sustainable energy sources. Unlike fossil fuels, which emit greenhouse gases and contribute to climate change, fusion has the potential to provide a clean and virtually limitless source of energy. The primary fuel for fusion, isotopes of hydrogen such as deuterium and tritium, can be extracted from water and lithium, making it widely available. Moreover, the byproducts of fusion reactions are generally non-toxic and do not pose a long-term waste disposal problem, unlike nuclear fission. Research into harnessing fusion heat for practical energy generation has been ongoing for decades, with projects like ITER (International Thermonuclear Experimental Reactor) leading the way. ITER aims to demonstrate the feasibility of fusion as a large-scale and carbon-free source of energy. If successful, it could revolutionize the global energy landscape, reducing our reliance on fossil fuels and helping to mitigate the impacts of climate change. However, achieving controlled nuclear fusion is an incredibly complex challenge. The conditions required for fusion – extremely high temperatures and pressures – are difficult to maintain. Scientists must create a plasma state where the nuclei can collide with enough energy to overcome their electrostatic repulsion. This is where the term fusion heat becomes critical; it is the heat generated that helps sustain these conditions. Researchers are exploring various methods, including magnetic confinement and inertial confinement, to achieve this goal.In conclusion, the significance of fusion heat extends beyond theoretical physics; it represents a beacon of hope for a sustainable energy future. As we continue to face the pressing challenges of climate change and dwindling fossil fuel reserves, the pursuit of harnessing fusion heat could provide a solution that not only meets our energy needs but also protects our planet for future generations. The journey towards achieving practical fusion energy is fraught with challenges, but the potential rewards make it an endeavor worth pursuing. Ultimately, understanding fusion heat is essential for anyone interested in the future of energy production. It embodies the intersection of science, technology, and environmental stewardship, reminding us that the quest for clean energy is not just a scientific challenge, but a moral imperative for humanity.

在物理学和能源生产领域，术语融合热指的是在核聚变反应中释放出的巨量热能。这些反应发生在两个轻原子核结合形成一个更重的原子核时，在这个过程中释放出能量。这个现象不仅是理解恒星过程的基础，而且对未来地球能源解决方案具有巨大潜力。例如，太阳通过氢原子的聚变生成氦，产生的融合热温暖了我们的星球并维持了生命。融合热的概念在关于可持续能源来源的讨论中尤为重要。与排放温室气体并导致气候变化的化石燃料不同，聚变有潜力提供一种清洁且几乎无限的能源来源。聚变的主要燃料，氢的同位素，如氘和氚，可以从水和锂中提取，使其广泛可用。此外，聚变反应的副产品通常是无毒的，并且不像核裂变那样带来长期废物处理问题。对利用融合热进行实际能源生产的研究已经持续了几十年，国际热核聚变实验反应堆（ITER）等项目走在前列。ITER旨在展示聚变作为大规模和无碳能源源的可行性。如果成功，它可能会彻底改变全球能源格局，减少我们对化石燃料的依赖，并帮助减轻气候变化的影响。然而，实现受控核聚变是一个极其复杂的挑战。聚变所需的条件——极高的温度和压力——很难维持。科学家们必须创造一种等离子态，使得原子核能够以足够的能量碰撞，以克服它们的静电排斥。此时，术语融合热变得至关重要；正是产生的热量帮助维持这些条件。研究人员正在探索各种方法，包括磁约束和惯性约束，以实现这一目标。总之，融合热的重要性超越了理论物理；它代表了可持续能源未来的希望。在我们继续面临气候变化和化石燃料储量日益枯竭的紧迫挑战时，追求利用融合热可能提供一种解决方案，不仅满足我们的能源需求，还保护我们星球的未来。实现实用聚变能源的旅程充满挑战，但潜在的回报使这一努力值得追求。最终，理解融合热对于任何对未来能源生产感兴趣的人来说都是至关重要的。它体现了科学、技术和环境保护之间的交汇，提醒我们，追求清洁能源不仅仅是科学挑战，更是人类的道德责任。