advanced stellarator

简明释义

改进型仿星器

英英释义

例句

1.Funding has been allocated for the construction of a new advanced stellarator 先进的恒星器 facility.

已拨款用于建设新的先进的恒星器 先进的恒星器设施。

2.Scientists believe that the advanced stellarator 先进的恒星器 could be key to achieving sustainable fusion energy.

科学家们相信，先进的恒星器 先进的恒星器可能是实现可持续核聚变能源的关键。

3.The advanced stellarator 先进的恒星器 aims to minimize turbulence in plasma.

该先进的恒星器 先进的恒星器旨在最小化等离子体中的湍流。

4.The design of the advanced stellarator 先进的恒星器 includes innovative magnetic configurations.

该先进的恒星器 先进的恒星器的设计包括创新的磁场配置。

5.The research team is developing an advanced stellarator 先进的恒星器 to improve plasma confinement.

研究团队正在开发一个先进的恒星器 先进的恒星器以改善等离子体约束。

作文

The quest for sustainable and clean energy has led scientists to explore various methods of harnessing nuclear fusion. One of the most promising technologies in this field is the advanced stellarator, which offers a unique approach to confining hot plasma needed for fusion reactions. Unlike traditional tokamaks, which use magnetic fields generated by electric currents, the advanced stellarator relies on complex magnetic configurations that can stabilize plasma without the need for large amounts of current. This characteristic makes the advanced stellarator particularly appealing, as it can potentially operate continuously without the disruptions that often plague tokamaks.The design of an advanced stellarator involves intricate geometries that create twisted magnetic fields. These fields are essential for maintaining the stability of the plasma, which can reach temperatures exceeding those found in the core of the sun. By carefully engineering these magnetic structures, researchers aim to achieve a balance between the forces acting on the plasma, allowing for longer confinement times and more efficient energy production.One of the significant advantages of the advanced stellarator is its ability to operate in steady-state conditions. This means that once the plasma is initiated, it can be maintained over extended periods, making it more suitable for practical energy generation. In contrast, conventional fusion reactors often face challenges related to short operational cycles and disruptions caused by instabilities in the plasma. The advanced stellarator, with its stable magnetic confinement, presents a solution to these issues, paving the way for future advancements in fusion technology.Moreover, the research surrounding the advanced stellarator has led to valuable insights into plasma physics and magnetic confinement. Facilities like the Wendelstein 7-X in Germany are at the forefront of this research, pushing the boundaries of what is possible in fusion energy. As scientists continue to refine the design and operation of the advanced stellarator, we may see significant breakthroughs that could revolutionize the energy landscape.In conclusion, the advanced stellarator represents a remarkable step forward in the pursuit of fusion energy. Its innovative approach to plasma confinement and stability offers hope for a future where clean, limitless energy is a reality. As research progresses, the advanced stellarator could play a crucial role in addressing the world's energy needs while minimizing environmental impacts. The journey towards harnessing the power of the stars is challenging, but with advancements like the advanced stellarator, we are one step closer to achieving this goal.

可持续和清洁能源的探索促使科学家们研究各种利用核聚变的方法。该领域最有前景的技术之一是先进的星际器，它为限制核聚变反应所需的高温等离子体提供了一种独特的方法。与传统的托卡马克不同，后者依赖于由电流生成的磁场，先进的星际器则依靠复杂的磁性配置来稳定等离子体，而无需大量电流。这一特性使得先进的星际器特别吸引人，因为它能够在没有托卡马克常常遭遇的扰动的情况下持续运行。先进的星际器的设计涉及复杂的几何形状，这些几何形状创建了扭曲的磁场。这些磁场对于维持等离子体的稳定性至关重要，等离子体的温度可以超过太阳核心的温度。通过精心设计这些磁性结构，研究人员旨在实现对作用于等离子体的力的平衡，从而实现更长的限制时间和更高效的能量产生。先进的星际器的一大显著优势是其能够在稳态条件下运行。这意味着一旦启动等离子体，它可以在较长时间内维持，这使其更适合实际的能量生成。相比之下，传统的聚变反应堆往往面临与短暂操作周期和等离子体不稳定性相关的挑战。凭借其稳定的磁约束，先进的星际器提供了应对这些问题的解决方案，为聚变技术的未来发展铺平了道路。此外，围绕先进的星际器的研究为等离子体物理学和磁约束提供了宝贵的见解。德国的温德尔施泰因7-X等设施处于这一研究的最前沿，推动着聚变能源可能性的边界。随着科学家们继续完善先进的星际器的设计和操作，我们可能会看到重大的突破，这可能会彻底改变能源格局。总之，先进的星际器代表了在追求聚变能源方面的一项显著进步。它对等离子体约束和稳定性的创新方法为实现清洁、无限的能源提供了希望。随着研究的进展，先进的星际器可能在满足全球能源需求的同时，最大限度地减少环境影响方面发挥关键作用。利用星星的力量的旅程充满挑战，但随着像先进的星际器这样的进步，我们离实现这一目标又近了一步。