fusion heat

简明释义

聚变热

英英释义

例句

1.The process of nuclear fusion generates immense amounts of fusion heat, which can be harnessed for energy production.

核聚变的过程产生巨大的聚变热，可以用于能源生产。

2.To understand the behavior of plasma, researchers measure the fusion heat produced in experiments.

为了理解等离子体的行为，研究人员测量实验中产生的聚变热。

3.Engineers are developing materials that can tolerate high levels of fusion heat without degrading.

工程师们正在开发能够耐受高水平聚变热而不降解的材料。

4.The reactor core must withstand the extreme fusion heat generated during the reaction.

反应堆核心必须承受在反应过程中产生的极端聚变热。

5.Scientists are studying how to contain fusion heat in order to achieve sustainable nuclear fusion.

科学家们正在研究如何控制聚变热以实现可持续的核聚变。

作文

In the realm of physics and engineering, the term fusion heat refers to the immense energy released during the process of nuclear fusion. This process occurs when two light atomic nuclei combine to form a heavier nucleus, resulting in the release of a significant amount of energy. Understanding fusion heat is crucial for various applications, particularly in the development of sustainable energy sources. Unlike fossil fuels, which emit greenhouse gases and contribute to climate change, nuclear fusion promises a cleaner alternative with abundant energy potential. The sun, for instance, generates its energy through fusion reactions, where hydrogen nuclei fuse to form helium, releasing tremendous amounts of heat and light that sustain life on Earth.The quest for harnessing fusion heat for human use has been ongoing for decades. Scientists and engineers are working tirelessly to create conditions similar to those found in the sun, where temperatures exceed millions of degrees Celsius. Achieving these conditions on Earth requires sophisticated technology and materials that can withstand extreme environments. The challenges of containing the plasma—an ionized gas composed of free electrons and nuclei—are formidable. Magnetic confinement and inertial confinement are two primary methods being explored to achieve this goal.One of the most promising projects in this field is the International Thermonuclear Experimental Reactor (ITER), located in France. ITER aims to demonstrate the feasibility of nuclear fusion as a large-scale and carbon-free source of energy. By producing more energy from fusion heat than is consumed to initiate the reaction, ITER could pave the way for future fusion power plants. If successful, it would mark a significant milestone in energy production, potentially providing a nearly limitless supply of clean energy.Moreover, the implications of successfully harnessing fusion heat extend beyond energy generation. It could lead to advancements in various sectors, including transportation, manufacturing, and even space exploration. For example, fusion propulsion systems could revolutionize space travel, allowing spacecraft to reach distant planets within a fraction of the time currently required.Despite the potential benefits, there are still significant hurdles to overcome. The initial investment in fusion research is substantial, and the timeline for achieving practical fusion energy remains uncertain. However, the global scientific community continues to collaborate, sharing knowledge and resources to expedite progress in this vital field. Public interest and investment in fusion technology are also growing, as awareness of climate change and the need for sustainable energy solutions increases.In conclusion, fusion heat represents a frontier in energy science, offering hope for a future where humanity can meet its energy needs without compromising the health of our planet. As research advances and technological breakthroughs occur, the dream of harnessing the power of the stars may soon become a reality. With continued dedication and innovation, fusion heat could transform the way we produce and consume energy, leading to a cleaner, more sustainable world for generations to come.

在物理学和工程学领域，术语融合热指的是在核聚变过程中释放的巨大能量。当两个轻原子核结合形成一个较重的原子核时，就会发生这种过程，从而释放出大量的能量。理解融合热对于各种应用至关重要，特别是在开发可持续能源方面。与化石燃料不同，化石燃料会排放温室气体并导致气候变化，核聚变则承诺提供一种更清洁的替代方案，拥有丰富的能源潜力。例如，太阳通过聚变反应产生能量，其中氢核融合形成氦，释放出巨大的热量和光线，维持着地球上的生命。人类对利用融合热的追求已经持续了几十年。科学家和工程师们正在不懈努力，以创造与太阳内部相似的条件，在那里温度超过数百万摄氏度。在地球上实现这些条件需要复杂的技术和能够承受极端环境的材料。控制等离子体（由自由电子和原子核组成的电离气体）的挑战是巨大的。磁约束和惯性约束是两种主要的方法，正在探索以实现这一目标。在这个领域中，最有前景的项目之一是位于法国的国际热核聚变实验堆（ITER）。ITER旨在证明核聚变作为大规模和无碳能源源的可行性。通过从融合热中产生比启动反应所消耗的更多能量，ITER可能为未来的聚变发电厂铺平道路。如果成功，这将标志着能源生产的重大里程碑，可能提供几乎无限的清洁能源供应。此外，成功利用融合热的影响超越了能源生产。这可能导致各个领域的进步，包括交通、制造业，甚至太空探索。例如，聚变推进系统可能彻底改变太空旅行，使宇宙飞船在当前所需时间的一小部分内到达遥远的行星。尽管潜在的好处，仍然存在重大的障碍需要克服。聚变研究的初始投资是巨大的，达到实用聚变能源的时间表仍然不确定。然而，全球科学界继续合作，分享知识和资源，以加快这一重要领域的进展。随着公众对气候变化和可持续能源解决方案需求的认识不断提高，对聚变技术的兴趣和投资也在增长。总之，融合热代表了能源科学的前沿，为人类能够满足其能源需求而不损害我们星球健康的未来带来了希望。随着研究的进展和技术突破的出现，利用恒星的力量的梦想可能很快成为现实。通过持续的奉献和创新，融合热可能会改变我们生产和消费能源的方式，为后代创造一个更清洁、更可持续的世界。