plasma confinement

简明释义

等离子体约束

英英释义

例句

1.The success of nuclear fusion experiments largely depends on effective plasma confinement.

核聚变实验的成功在很大程度上依赖于有效的等离子体约束。

2.Advanced magnetic fields are essential for achieving stable plasma confinement.

先进的磁场对于实现稳定的等离子体约束至关重要。

3.The ITER project aims to demonstrate the feasibility of plasma confinement for sustainable energy.

国际热核聚变实验堆（ITER）项目旨在展示可持续能源的等离子体约束的可行性。

4.Researchers are exploring new materials to improve plasma confinement in fusion reactors.

研究人员正在探索新材料，以改善聚变反应堆中的等离子体约束。

5.Without proper plasma confinement, the energy produced in fusion reactions would be lost.

如果没有适当的等离子体约束，聚变反应中产生的能量将会流失。

作文

Plasma confinement is a critical concept in the field of nuclear fusion, which is often seen as the holy grail of energy production. In essence, plasma confinement (等离子体约束) refers to the techniques used to contain plasma, a state of matter where electrons are separated from their nuclei, allowing for the conditions necessary for fusion reactions to occur. The challenge lies in maintaining the stability and integrity of the plasma while achieving the high temperatures and pressures required for fusion. One of the most promising methods of plasma confinement (等离子体约束) is magnetic confinement, utilized in devices such as tokamaks and stellarators. These devices use powerful magnetic fields to create a stable environment for the plasma, preventing it from coming into contact with the walls of the containment vessel. The ability to confine plasma effectively is essential for sustaining the fusion process long enough to produce a net energy gain. Another approach to plasma confinement (等离子体约束) is inertial confinement, which involves compressing small pellets of fusion fuel using powerful lasers or other forms of energy. The rapid compression raises the temperature and pressure of the fuel, leading to conditions conducive to fusion. Each method presents unique challenges and advantages, but both highlight the importance of effective plasma confinement (等离子体约束) in achieving practical fusion energy. The implications of successfully mastering plasma confinement (等离子体约束) are profound. Fusion has the potential to provide a nearly limitless source of clean energy, significantly reducing our reliance on fossil fuels and minimizing greenhouse gas emissions. However, the technical hurdles remain substantial. Researchers around the world continue to explore innovative solutions to improve plasma confinement (等离子体约束) techniques, aiming to create a sustainable and economically viable fusion reactor. In conclusion, understanding plasma confinement (等离子体约束) is vital for anyone interested in the future of energy production. As we face the challenges of climate change and dwindling fossil fuel reserves, the pursuit of fusion energy becomes increasingly urgent. By advancing our knowledge and technology related to plasma confinement (等离子体约束), we move one step closer to unlocking the potential of nuclear fusion as a safe, sustainable energy source for future generations.

等离子体约束是核聚变领域中的一个关键概念，通常被视为能源生产的圣杯。简而言之，plasma confinement（等离子体约束）指的是用于限制等离子体的技术，等离子体是一种物质状态，其中电子与其原子核分离，从而允许发生聚变反应所需的条件。挑战在于在实现高温和高压的同时，保持等离子体的稳定性和完整性。其中一种最有前景的plasma confinement（等离子体约束）方法是磁约束，利用如托卡马克和恒星器等装置。这些装置使用强大的磁场来创造一个稳定的等离子体环境，防止其与容器壁接触。有效地限制等离子体的能力对于维持聚变过程足够长的时间以产生净能量增益至关重要。另一种plasma confinement（等离子体约束）方法是惯性约束，它涉及使用强激光或其他形式的能量压缩小型聚变燃料颗粒。快速压缩提高了燃料的温度和压力，导致适合聚变的条件。每种方法都有独特的挑战和优势，但两者都突显了有效plasma confinement（等离子体约束）在实现实用聚变能源中的重要性。成功掌握plasma confinement（等离子体约束）的意义深远。聚变有潜力提供几乎无限的清洁能源，显著减少我们对化石燃料的依赖，并最小化温室气体排放。然而，技术障碍仍然相当重大。全球的研究人员继续探索创新解决方案，以改善plasma confinement（等离子体约束）技术，旨在创建一个可持续和经济上可行的聚变反应堆。总之，理解plasma confinement（等离子体约束）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。在我们面临气候变化和化石燃料储备日益减少的挑战时，追求聚变能源变得越来越紧迫。通过推进与plasma confinement（等离子体约束）相关的知识和技术，我们向解锁聚变作为安全、可持续的能源来源的潜力更进一步。