fusion current

简明释义

熔化电流

英英释义

例句

1.Monitoring the fusion current 聚变电流 is crucial for maintaining safety in nuclear fusion reactors.

监测fusion current 聚变电流对维持核聚变反应堆的安全至关重要。

2.The team adjusted the magnetic fields to optimize the fusion current 聚变电流 in their latest experiment.

团队调整了磁场以优化他们最新实验中的fusion current 聚变电流。

3.The researchers measured the fusion current 聚变电流 in the experimental reactor to ensure optimal performance.

研究人员在实验反应堆中测量了fusion current 聚变电流以确保最佳性能。

4.The increase in fusion current 聚变电流 led to a breakthrough in energy output during the tests.

测试中fusion current 聚变电流的增加导致了能量输出的突破。

5.Increasing the fusion current 聚变电流 can enhance the stability of the plasma.

增加fusion current 聚变电流可以增强等离子体的稳定性。

作文

In the realm of physics, particularly in the study of plasma and nuclear fusion, the term fusion current refers to the flow of charged particles that are generated during the process of nuclear fusion. This phenomenon is crucial for understanding how stars, including our Sun, generate energy through fusion reactions. The fusion current plays a pivotal role in maintaining the stability of the plasma and ensuring that the conditions necessary for fusion are met. In essence, it is the movement of ions and electrons that contributes to the overall energy output of a fusion reaction.To grasp the significance of fusion current, one must first understand the basics of nuclear fusion. Fusion occurs when two light atomic nuclei combine to form a heavier nucleus, releasing a tremendous amount of energy in the process. This is the fundamental reaction that powers stars. For fusion to take place, extremely high temperatures and pressures are required, conditions that can be found in the cores of stars. When these conditions are achieved, the kinetic energy of the particles increases, leading to a higher likelihood of collisions between nuclei.The fusion current is generated as a result of these high-energy collisions. As ions collide, they can become ionized, creating a plasma made up of free electrons and positively charged ions. The movement of these charged particles constitutes the fusion current. This current is essential for sustaining the magnetic fields that confine the plasma in experimental fusion reactors, such as tokamaks and stellarators.In fusion research, understanding the behavior of the fusion current is vital for optimizing the efficiency of fusion reactors. Scientists aim to control this current to enhance confinement and minimize energy losses. By manipulating the fusion current, researchers can improve the stability of the plasma, which is necessary for achieving sustained fusion reactions. This is particularly important when considering the potential for fusion energy as a clean and virtually limitless source of power for the future.Moreover, the study of fusion current also has implications beyond energy production. Understanding the dynamics of fusion current can provide insights into astrophysical phenomena, such as solar flares and the behavior of other celestial bodies. These insights can help scientists better comprehend the processes that govern the universe and the lifecycle of stars.In conclusion, the concept of fusion current is integral to the field of nuclear fusion and plasma physics. It represents the flow of charged particles that is crucial for sustaining the conditions necessary for fusion reactions. As researchers continue to explore the possibilities of harnessing fusion energy, the understanding of fusion current will remain a key focus. By mastering this concept, scientists hope to unlock the potential of fusion as a safe, sustainable, and powerful energy source for generations to come.

在物理学的领域，特别是在等离子体和核聚变的研究中，术语fusion current指的是在核聚变过程中产生的带电粒子的流动。这一现象对于理解恒星（包括我们的太阳）如何通过聚变反应产生能量至关重要。fusion current在维持等离子体的稳定性和确保满足聚变所需条件方面发挥着关键作用。实际上，它是离子和电子的运动，有助于聚变反应的整体能量输出。要理解fusion current的重要性，首先必须了解核聚变的基本知识。聚变发生在两个轻原子核结合形成一个更重的原子核时，并在此过程中释放出巨大的能量。这是驱动恒星的基本反应。为了使聚变发生，需要极高的温度和压力，这些条件可以在恒星的核心找到。当这些条件达到时，粒子的动能增加，从而提高了原子核碰撞的可能性。fusion current是由于这些高能碰撞而产生的。当离子碰撞时，它们可以被电离，形成由自由电子和带正电的离子组成的等离子体。这些带电粒子的运动构成了fusion current。这一电流对于维持实验聚变反应堆（如托卡马克和恒星器）中束缚等离子体的磁场至关重要。在聚变研究中，理解fusion current的行为对于优化聚变反应堆的效率至关重要。科学家们旨在控制这一电流，以增强约束并最小化能量损失。通过操控fusion current，研究人员可以改善等离子体的稳定性，这是实现持续聚变反应所必需的。在考虑聚变能作为未来清洁和几乎无限的能源来源时，这一点尤其重要。此外，fusion current的研究还具有超越能源生产的意义。理解fusion current的动态可以提供对天体物理现象的见解，例如太阳耀斑和其他天体的行为。这些见解可以帮助科学家更好地理解支配宇宙和恒星生命周期的过程。总之，fusion current的概念对于核聚变和等离子体物理领域至关重要。它代表了带电粒子的流动，这对维持聚变反应所需的条件至关重要。随着研究人员继续探索利用聚变能源的可能性，对fusion current的理解将始终是一个关键焦点。通过掌握这一概念，科学家希望释放聚变作为安全、可持续和强大能源来源的潜力，造福未来几代人。