radiation sensitive material
简明释义
辐射灵敏材料
英英释义
Materials that exhibit a change in their properties or behavior when exposed to radiation, such as ionizing radiation or electromagnetic radiation. | 在暴露于辐射(如电离辐射或电磁辐射)时,其性质或行为发生变化的材料。 |
例句
1.The lab is equipped with special storage for radiation sensitive material to prevent exposure.
实验室配备了特殊的存储空间,以防止暴露于辐射敏感材料。
2.The packaging for radiation sensitive material must be clearly labeled.
对辐射敏感材料的包装必须清晰标示。
3.Proper disposal methods for radiation sensitive material are crucial for safety.
对辐射敏感材料的适当处理方法对安全至关重要。
4.Researchers are studying the effects of radiation sensitive material on electronic components.
研究人员正在研究辐射敏感材料对电子元件的影响。
5.When handling radiation sensitive material, always wear protective gear.
处理辐射敏感材料时,务必穿戴保护装备。
作文
In the field of science and technology, the term radiation sensitive material refers to substances that react to various forms of radiation, including electromagnetic radiation such as X-rays and gamma rays, as well as particle radiation like alpha and beta particles. These materials are crucial in a variety of applications ranging from medical imaging to nuclear energy. Understanding how radiation sensitive material works is essential for advancements in these fields.One of the most common uses of radiation sensitive material is in the development of photographic films and sensors. Traditional photographic film contains silver halides that undergo a chemical change when exposed to light or radiation. This property allows for the capture of images, making it invaluable in photography and imaging technologies. In modern times, digital sensors have largely replaced film; however, the principles behind radiation sensitive material remain the same, as many sensors still rely on materials that respond to radiation in a specific way.In the medical field, radiation sensitive material plays a significant role in diagnostic imaging techniques such as X-rays and CT scans. The materials used in these imaging devices must be highly sensitive to radiation to produce clear and accurate images of the internal structures of the body. For instance, certain phosphor materials are used in X-ray detectors because they emit light when exposed to radiation. This light is then captured and converted into an image, allowing doctors to diagnose conditions effectively.Moreover, radiation sensitive material is also vital in radiation therapy, a common treatment for cancer. In this context, materials that can detect and measure radiation levels are essential for ensuring that patients receive the correct dosage during their treatment. Additionally, researchers are constantly developing new radiation sensitive materials to improve the efficacy and safety of these treatments, highlighting the ongoing importance of this field.In nuclear energy, radiation sensitive material is used to monitor and control radiation levels in reactors. Materials that can withstand high levels of radiation while providing accurate readings are critical for maintaining safety protocols. Furthermore, advancements in radiation sensitive materials have led to the development of better shielding materials that protect workers and the environment from harmful radiation exposure.The study of radiation sensitive material is not limited to just practical applications; it also encompasses theoretical research. Scientists are continually investigating the properties of various materials to understand how they interact with different types of radiation. This research can lead to the discovery of new materials that are even more effective at detecting or shielding against radiation.In conclusion, radiation sensitive material is an integral part of many technological advances in fields such as photography, medicine, and nuclear energy. Its ability to react to radiation makes it invaluable for both practical applications and scientific research. As technology continues to evolve, the importance of understanding and improving radiation sensitive material will only grow, paving the way for innovations that enhance safety and efficiency in various industries.
在科学和技术领域,术语辐射敏感材料指的是对各种形式的辐射做出反应的物质,包括电磁辐射(如X射线和伽马射线)以及粒子辐射(如α粒子和β粒子)。这些材料在从医学成像到核能等多个应用中至关重要。理解辐射敏感材料的工作原理对这些领域的进步至关重要。辐射敏感材料最常见的用途之一是在摄影胶卷和传感器的开发中。传统的摄影胶卷包含在光或辐射照射下发生化学变化的卤化银。这种特性使得捕捉图像成为可能,使其在摄影和成像技术中不可或缺。在现代,数字传感器在很大程度上取代了胶卷;然而,辐射敏感材料背后的原理仍然相同,因为许多传感器仍然依赖于以特定方式响应辐射的材料。在医学领域,辐射敏感材料在X射线和CT扫描等诊断成像技术中发挥着重要作用。这些成像设备中使用的材料必须对辐射高度敏感,以产生清晰准确的身体内部结构图像。例如,某些磷光材料用于X射线探测器,因为它们在暴露于辐射时会发光。这种光被捕获并转换为图像,允许医生有效地诊断疾病。此外,辐射敏感材料在放射治疗中也至关重要,这是癌症的一种常见治疗方法。在这种情况下,可以检测和测量辐射水平的材料对于确保患者在治疗期间接受正确剂量至关重要。此外,研究人员不断开发新的辐射敏感材料,以提高这些治疗的有效性和安全性,突显了这一领域的持续重要性。在核能领域,辐射敏感材料用于监测和控制反应堆中的辐射水平。能够承受高辐射水平同时提供准确读数的材料对于维持安全协议至关重要。此外,辐射敏感材料的进步导致了更好的屏蔽材料的发展,这些材料保护工人和环境免受有害辐射的影响。对辐射敏感材料的研究不仅限于实际应用;它还涵盖理论研究。科学家们不断研究各种材料的特性,以了解它们如何与不同类型的辐射相互作用。这项研究可能导致发现新的材料,这些材料在检测或屏蔽辐射方面更有效。总之,辐射敏感材料是摄影、医学和核能等许多技术进步的重要组成部分。它对辐射的反应能力使其在实际应用和科学研究中都具有不可替代的价值。随着技术的不断发展,理解和改进辐射敏感材料的重要性只会增加,为各个行业的安全和效率提升铺平道路。
