fusion energy research facility

简明释义

聚变能研究装置

英英释义

例句

1.Visitors can tour the fusion energy research facility 聚变能源研究设施 to learn about the latest developments in fusion technology.

游客可以参观聚变能源研究设施 fusion energy research facility，了解聚变技术的最新进展。

2.Scientists at the fusion energy research facility 聚变能源研究设施 are working on achieving a stable plasma state for better energy production.

在聚变能源研究设施 fusion energy research facility的科学家们正在努力实现稳定的等离子体状态，以提高能源生产效率。

3.The fusion energy research facility 聚变能源研究设施 aims to replicate the sun's energy production process on Earth.

该聚变能源研究设施 fusion energy research facility旨在在地球上复制太阳的能量生产过程。

4.The government has allocated significant funding to the new fusion energy research facility 聚变能源研究设施 to accelerate advancements in sustainable energy.

政府已向新的聚变能源研究设施 fusion energy research facility拨款，以加速可持续能源的进步。

5.The collaboration between universities and the fusion energy research facility 聚变能源研究设施 is expected to yield groundbreaking results.

大学与聚变能源研究设施 fusion energy research facility之间的合作预计将产生突破性的成果。

作文

In recent years, the global demand for clean and sustainable energy sources has prompted significant advancements in various fields of research. One of the most promising avenues is nuclear fusion, which has the potential to provide an almost limitless source of energy without the harmful byproducts associated with fossil fuels. To explore this potential, scientists and engineers around the world are establishing specialized centers known as fusion energy research facilities (聚变能源研究设施). These facilities are dedicated to investigating the intricacies of fusion reactions and developing technologies that can harness this powerful energy source.A fusion energy research facility typically focuses on replicating the processes that power the sun. In essence, fusion occurs when two light atomic nuclei combine to form a heavier nucleus, releasing a tremendous amount of energy in the process. Unlike nuclear fission, which splits heavy atoms and produces radioactive waste, fusion promises a cleaner alternative, utilizing isotopes of hydrogen, such as deuterium and tritium, which are abundant in nature.The establishment of fusion energy research facilities is crucial for advancing our understanding of plasma physics—the state of matter where electrons are stripped from atoms, creating a soup of charged particles. This state is essential for achieving the conditions necessary for fusion to occur. Researchers use advanced techniques and technologies, including magnetic confinement and inertial confinement, to control and sustain these high-energy plasmas. Facilities like the ITER (International Thermonuclear Experimental Reactor) in France represent international collaboration efforts aimed at making fusion a viable energy source.The work conducted at fusion energy research facilities is not only focused on energy production but also on addressing safety concerns. Fusion reactions do not carry the same risks as fission, as they require extremely precise conditions to be maintained. Furthermore, if a disruption occurs, the reaction simply stops, eliminating the risk of a meltdown. This inherent safety feature makes fusion an attractive option for future energy needs.Moreover, the environmental benefits of fusion energy cannot be overstated. A fusion energy research facility aims to develop technology that produces minimal waste and has a significantly lower carbon footprint compared to traditional energy sources. The fuel for fusion is derived from water and lithium, making it a sustainable choice for the long term. As the global community grapples with climate change and seeks to reduce greenhouse gas emissions, the role of fusion energy becomes increasingly vital.In conclusion, the establishment of fusion energy research facilities is a critical step toward realizing the dream of clean, abundant energy through nuclear fusion. These centers not only push the boundaries of scientific knowledge but also pave the way for a sustainable energy future. As research progresses, we may find ourselves on the brink of a new era in energy production, one that harnesses the power of the stars and provides a solution to some of the most pressing challenges facing humanity today.

近年来，全球对清洁和可持续能源的需求促使各个研究领域的重大进展。其中最有前景的途径之一是核聚变，它有潜力提供几乎无限的能源来源，而不会产生与化石燃料相关的有害副产品。为了探索这一潜力，世界各地的科学家和工程师正在建立专门的中心，称为聚变能源研究设施（fusion energy research facilities）。这些设施致力于研究聚变反应的复杂性，并开发能够利用这一强大能源的技术。一个聚变能源研究设施通常专注于复制太阳的能量产生过程。实际上，聚变发生在两个轻原子核结合形成一个较重的原子核时，并在此过程中释放出大量能量。与裂变不同，裂变是分裂重原子并产生放射性废物，聚变承诺提供一种更清洁的替代方案，利用氢的同位素，如氘和氚，这些在自然界中丰富存在。建立聚变能源研究设施对于推进我们对等离子体物理学的理解至关重要——这是物质的一种状态，其中电子从原子中剥离，形成带电粒子的汤。这种状态对于实现聚变所需的条件至关重要。研究人员使用先进的技术和设备，包括磁约束和惯性约束，来控制和维持这些高能等离子体。像法国的国际热核聚变实验堆（ITER）这样的设施代表了国际合作努力，旨在使聚变成为一种可行的能源来源。在聚变能源研究设施进行的工作不仅关注能源生产，还关注安全问题。聚变反应没有裂变的风险，因为它们需要极其精确的条件来维持。此外，如果发生干扰，反应会立即停止，从而消除熔毁的风险。这一固有的安全特性使聚变成为未来能源需求的一个有吸引力的选择。此外，聚变能源的环境效益不容低估。聚变能源研究设施旨在开发产生最少废物且相较于传统能源源具有显著较低碳足迹的技术。聚变的燃料来自水和锂，使其成为长期可持续的选择。随着全球社会应对气候变化并寻求减少温室气体排放，聚变能源的角色变得越来越重要。总之，建立聚变能源研究设施是实现通过核聚变获得清洁、丰富能源梦想的重要一步。这些中心不仅推动科学知识的边界，还为可持续能源的未来铺平道路。随着研究的进展，我们可能会发现自己处于能源生产的新纪元的边缘，一个利用星星的力量并为人类今天面临的一些最紧迫的挑战提供解决方案的时代。