irradiated plasma

简明释义

辐照等离子体

英英释义

例句

1.In the experiment, the irradiated plasma was used to sterilize surgical instruments.

在实验中，辐照等离子体被用来消毒手术器械。

2.Scientists are studying the properties of irradiated plasma for potential applications in fusion energy.

科学家们正在研究辐照等离子体的特性，以寻找其在聚变能源中的潜在应用。

3.The use of irradiated plasma in material processing can enhance surface characteristics.

在材料加工中使用辐照等离子体可以增强表面特性。

4.The irradiated plasma generated during the process can be harnessed for energy production.

在该过程中产生的辐照等离子体可以用于能源生产。

5.The researchers observed the effects of the irradiated plasma on microbial cells.

研究人员观察了辐照等离子体对微生物细胞的影响。

作文

The study of plasma physics is a fascinating field that encompasses various applications, including fusion energy and space exploration. One of the critical components in this area is the concept of irradiated plasma, which refers to plasma that has been exposed to radiation. Understanding irradiated plasma is essential for scientists and engineers working on advanced technologies. Plasma, often described as the fourth state of matter, consists of ionized gases containing free electrons and ions. When this plasma is subjected to radiation, it undergoes significant changes in its properties. The interaction between the radiation and the plasma can lead to various phenomena, such as increased temperature, enhanced ionization, and even the generation of new particles. These changes are crucial for applications like nuclear fusion, where irradiated plasma can facilitate the conditions necessary for energy production. In fusion reactors, for instance, irradiated plasma plays a pivotal role. By heating the plasma to extremely high temperatures and maintaining it under specific conditions, scientists aim to replicate the processes that occur in the sun. The challenge lies in controlling the irradiated plasma to achieve stable fusion reactions. Researchers use magnetic confinement and inertial confinement techniques to contain the plasma, ensuring that it remains stable despite the intense energy levels involved. Moreover, the study of irradiated plasma extends beyond fusion energy. In astrophysics, understanding how plasma behaves under radiation helps scientists comprehend the dynamics of stars and other celestial bodies. For example, when studying solar flares, researchers analyze the irradiated plasma emitted by the sun to predict space weather events that can impact satellites and communication systems on Earth. Furthermore, irradiated plasma has applications in materials science. When materials are exposed to plasma irradiation, their surface properties can be modified, leading to enhanced durability, corrosion resistance, and other beneficial traits. This process is utilized in industries ranging from aerospace to electronics, showcasing the versatility of irradiated plasma in technological advancements. In conclusion, irradiated plasma is a vital concept within plasma physics that influences numerous fields, including energy production, astrophysics, and materials science. As research continues to advance, the understanding and manipulation of irradiated plasma will undoubtedly lead to groundbreaking innovations and a deeper comprehension of the universe around us. Scientists and engineers must continue to explore this intriguing area to unlock its full potential and address the challenges of tomorrow.

等离子体物理的研究是一个迷人的领域，涵盖了多种应用，包括聚变能源和太空探索。在这个领域中，一个关键的组成部分是“irradiated plasma”的概念，指的是已被辐射暴露的等离子体。理解irradiated plasma对于从事先进技术工作的科学家和工程师至关重要。等离子体通常被描述为物质的第四种状态，由带电气体组成，包含自由电子和离子。当这种等离子体受到辐射时，其性质会发生显著变化。辐射与等离子体之间的相互作用可以导致多种现象，例如温度升高、离子化增强，甚至新粒子的产生。这些变化对于像核聚变这样的应用至关重要，其中irradiated plasma可以促进产生能量所需的条件。例如，在聚变反应堆中，irradiated plasma发挥着关键作用。通过将等离子体加热到极高的温度并在特定条件下维持它，科学家们旨在复制太阳发生的过程。挑战在于控制irradiated plasma以实现稳定的聚变反应。研究人员使用磁约束和惯性约束技术来限制等离子体，确保它在涉及的强烈能量水平下保持稳定。此外，对irradiated plasma的研究超越了聚变能源。在天体物理学中，理解等离子体在辐射下的行为有助于科学家理解恒星和其他天体的动态。例如，在研究太阳耀斑时，研究人员分析太阳发出的irradiated plasma，以预测可能影响地球上卫星和通信系统的空间天气事件。此外，irradiated plasma在材料科学中也有应用。当材料暴露于等离子体辐射时，其表面特性可以得到改良，从而提高耐久性、抗腐蚀性和其他有益特性。这一过程在航空航天到电子等行业中得到应用，展示了irradiated plasma在技术进步中的多样性。总之，irradiated plasma是等离子体物理学中的一个重要概念，影响着多个领域，包括能源生产、天体物理学和材料科学。随着研究的不断推进，对irradiated plasma的理解和操控无疑将引领突破性的创新，并加深我们对周围宇宙的理解。科学家和工程师必须继续探索这一引人入胜的领域，以释放其全部潜力并应对未来的挑战。