radiolytic weight loss

简明释义

辐解重量损失

英英释义

例句

1.Researchers found that the radiolytic weight loss (辐射分解质量损失) in the sample was higher than expected due to impurities.

研究人员发现，由于杂质，样本中的辐射分解质量损失高于预期。

2.To assess the durability of materials, scientists measured the radiolytic weight loss (辐射分解质量损失) in various conditions.

为了评估材料的耐久性，科学家们在不同条件下测量了辐射分解质量损失。

3.The radiolytic weight loss (辐射分解质量损失) observed in the experiment indicated a breakdown of molecular structure.

实验中观察到的辐射分解质量损失表明分子结构发生了破坏。

4.The study revealed that the polymer experienced significant radiolytic weight loss (辐射分解质量损失) after prolonged exposure to gamma radiation.

研究显示该聚合物在长时间暴露于伽马辐射后经历了显著的辐射分解质量损失。

5.In the context of nuclear waste management, radiolytic weight loss (辐射分解质量损失) is a critical factor to consider.

在核废料管理的背景下，辐射分解质量损失是一个重要的考虑因素。

作文

Radiation has long been a topic of interest in various fields, including medicine, energy production, and environmental science. One particularly intriguing phenomenon associated with radiation is radiolytic weight loss, which refers to the loss of mass in materials due to the effects of ionizing radiation. This process occurs when high-energy radiation interacts with matter, leading to the breakdown of molecular structures and subsequent release of gases or other byproducts. Understanding radiolytic weight loss is crucial for several reasons, particularly in the context of nuclear waste management and the longevity of materials used in nuclear reactors.In nuclear power plants, materials such as fuel rods and structural components are constantly exposed to high levels of radiation. Over time, this exposure can lead to radiolytic weight loss, which may compromise the integrity of these materials. For instance, when water is used as a coolant, it can undergo radiolysis, resulting in the formation of hydrogen and oxygen gases. As these gases escape, the overall mass of the coolant system decreases, potentially affecting its efficiency and safety. Therefore, understanding how radiolytic weight loss occurs and finding ways to mitigate its effects is essential for ensuring the safe operation of nuclear facilities.Moreover, radiolytic weight loss is not limited to industrial applications; it also has implications for the storage and disposal of radioactive waste. When radioactive materials are stored, they often undergo radiolytic processes that can lead to the degradation of containment materials. This degradation could result in leaks or the release of radioactive substances into the environment, posing significant risks to public health and safety. By studying radiolytic weight loss, researchers can develop better materials that are more resistant to radiation and can enhance the safety of waste storage solutions.In addition to the practical implications, radiolytic weight loss also raises fundamental questions about the nature of matter and energy. The interactions between radiation and materials provide insights into the stability of various compounds under extreme conditions. Researchers are exploring how different materials respond to radiation exposure, which can lead to advancements in material science and engineering. For example, understanding the mechanisms behind radiolytic weight loss could help in designing new materials that are more resilient to radiation, thereby extending their lifespan and functionality.Furthermore, the study of radiolytic weight loss contributes to our understanding of environmental processes. In natural settings, radiation from cosmic sources or terrestrial radioisotopes can induce similar weight loss phenomena in organic materials. This aspect of radiolytic weight loss is particularly relevant in the context of climate change and environmental degradation, where understanding the fate of organic matter in irradiated environments can inform conservation efforts.In conclusion, radiolytic weight loss is a complex phenomenon that has significant implications across various domains. From ensuring the safety of nuclear power plants to advancing material science and understanding environmental processes, the study of radiolytic weight loss is vital. As we continue to explore the effects of radiation on materials, we can develop strategies to mitigate its impacts, ultimately contributing to safer and more sustainable practices in both industry and environmental management.

辐射长期以来一直是医学、能源生产和环境科学等多个领域的一个重要话题。与辐射相关的一个特别引人入胜的现象是辐射损失质量，它指的是材料由于电离辐射的影响而导致的质量损失。当高能辐射与物质相互作用时，会导致分子结构的破坏，并随后释放气体或其他副产品。理解辐射损失质量至关重要，特别是在核废料管理和核反应堆中使用材料的耐久性方面。在核电站，燃料棒和结构组件等材料不断暴露在高水平的辐射下。随着时间的推移，这种暴露可能导致辐射损失质量，从而妨碍这些材料的完整性。例如，当水被用作冷却剂时，它可能经历辐解，导致氢和氧气体的形成。随着这些气体的逸出，冷却系统的总体质量减少，可能影响其效率和安全性。因此，理解辐射损失质量的发生方式并寻找减轻其影响的方法对于确保核设施的安全运行至关重要。此外，辐射损失质量不仅限于工业应用；它还对放射性废物的储存和处置产生影响。当放射性材料被储存时，它们通常会经历辐射过程，导致封闭材料的降解。这种降解可能导致泄漏或放射性物质释放到环境中，给公众健康和安全带来重大风险。通过研究辐射损失质量，研究人员可以开发出更耐辐射的材料，从而增强废物储存解决方案的安全性。除了实际影响外，辐射损失质量还引发了关于物质和能量本质的基本问题。辐射与材料之间的相互作用为我们提供了在极端条件下各种化合物稳定性的见解。研究人员正在探索不同材料如何响应辐射暴露，这可能会推动材料科学和工程的进步。例如，理解辐射损失质量背后的机制可以帮助设计出更耐辐射的新材料，从而延长它们的使用寿命和功能。此外，辐射损失质量的研究有助于我们理解环境过程。在自然环境中，来自宇宙源或地球放射性同位素的辐射可能在有机材料中引发类似的质量损失现象。这个方面的辐射损失质量在气候变化和环境退化的背景下尤为相关，因为理解辐照环境中有机物的命运可以为保护工作提供信息。总之，辐射损失质量是一个复杂的现象，在各个领域都有重要的影响。从确保核电站的安全到推动材料科学和理解环境过程，研究辐射损失质量至关重要。随着我们继续探索辐射对材料的影响，我们可以制定减轻其影响的策略，最终为工业和环境管理中的更安全、更可持续的实践做出贡献。