yield of radiation

简明释义

辐射强度

英英释义

例句

1.Researchers are studying the yield of radiation 辐射产量 from different isotopes to improve medical imaging techniques.

研究人员正在研究不同同位素的yield of radiation 辐射产量以改进医学成像技术。

2.The safety protocols were updated to account for the potential yield of radiation 辐射产量 during a containment breach.

安全协议已更新，以考虑在封闭失效期间可能的yield of radiation 辐射产量。

3.The nuclear reactor was designed to maximize the yield of radiation 辐射产量 for energy production.

这座核反应堆的设计旨在最大化yield of radiation 辐射产量以进行能量生产。

4.The experiment aimed to measure the yield of radiation 辐射产量 produced by the decay of radioactive materials.

该实验旨在测量放射性材料衰变产生的yield of radiation 辐射产量。

5.In astrophysics, the yield of radiation 辐射产量 from stars helps scientists understand their life cycles.

在天体物理学中，星星的yield of radiation 辐射产量帮助科学家理解它们的生命周期。

作文

The study of radiation is a crucial aspect of modern science, particularly in fields such as physics, medicine, and environmental science. One important concept within this realm is the yield of radiation, which refers to the amount of energy emitted in the form of radiation from a given source. Understanding the yield of radiation is essential for various applications, including nuclear power generation, medical imaging, and radiation therapy. In nuclear power plants, the yield of radiation plays a vital role in determining how much energy can be harnessed from nuclear reactions. When atoms are split in a process known as fission, they release a significant amount of energy, which can be converted into electricity. The efficiency of this conversion heavily relies on understanding the yield of radiation produced during the reaction. Engineers and scientists must calculate the yield of radiation to ensure that the plant operates safely and efficiently while minimizing waste and environmental impact.In the medical field, the yield of radiation is critical in diagnostic imaging techniques such as X-rays and CT scans. These procedures utilize controlled amounts of radiation to create detailed images of the body’s internal structures. Medical professionals must carefully monitor the yield of radiation to balance the need for clear images with the potential risks associated with exposure to radiation. Too high a yield of radiation can lead to harmful effects, including increased cancer risk, so it is imperative to use the lowest effective dose possible.Furthermore, in the context of radiation therapy for cancer treatment, the yield of radiation is manipulated to target and destroy malignant cells while sparing healthy tissue. Oncologists must calculate the optimal yield of radiation to maximize the treatment's effectiveness while minimizing side effects. This delicate balance is achieved through advanced techniques and equipment that allow precise delivery of radiation doses.Environmental scientists also study the yield of radiation in relation to natural sources, such as cosmic rays and radon gas, as well as artificial sources from human activities. Understanding the yield of radiation in these contexts is essential for assessing exposure risks to humans and ecosystems. For instance, monitoring the yield of radiation from radon in homes can help prevent health hazards associated with long-term exposure.In conclusion, the yield of radiation is a fundamental concept that intersects various scientific disciplines. Its implications are far-reaching, affecting energy production, medical practices, and environmental safety. As technology advances, our ability to measure and manipulate the yield of radiation will continue to improve, leading to safer and more efficient applications. It is imperative for future scientists and engineers to grasp the nuances of the yield of radiation to innovate responsibly and ethically in their respective fields.

辐射研究是现代科学的重要方面，特别是在物理学、医学和环境科学等领域。这个领域内一个重要的概念是辐射的产量，它指的是从给定源发出的以辐射形式释放的能量量。理解辐射的产量对于核能发电、医学成像和放射治疗等各种应用至关重要。在核电站中，辐射的产量在确定可以从核反应中获取多少能量方面起着关键作用。当原子在称为裂变的过程中被分裂时，它们释放出大量能量，这些能量可以转化为电力。这种转化的效率在很大程度上依赖于对反应中产生的辐射的产量的理解。工程师和科学家必须计算辐射的产量，以确保电厂安全高效地运行，同时最小化废物和环境影响。在医学领域，辐射的产量在诊断成像技术（如X射线和CT扫描）中至关重要。这些程序利用控制的辐射量来创建身体内部结构的详细图像。医疗专业人员必须仔细监测辐射的产量，以平衡清晰图像的需求与辐射暴露可能带来的风险。过高的辐射的产量可能导致有害影响，包括增加癌症风险，因此必须使用尽可能低的有效剂量。此外，在癌症治疗的放射治疗背景下，辐射的产量被操控以针对和摧毁恶性细胞，同时保护健康组织。肿瘤科医生必须计算最佳的辐射的产量，以最大限度地提高治疗效果，同时减少副作用。通过先进的技术和设备，可以精确地输送辐射剂量，从而实现这种微妙的平衡。环境科学家还研究自然源的辐射的产量，例如宇宙射线和氡气，以及人类活动产生的人造源。理解这些背景下的辐射的产量对于评估人类和生态系统的暴露风险至关重要。例如，监测家庭中氡气的辐射的产量可以帮助防止与长期暴露相关的健康危害。总之，辐射的产量是一个基本概念，交叉了多个科学学科。它的影响深远，涉及能源生产、医疗实践和环境安全。随着技术的进步，我们测量和操控辐射的产量的能力将继续提高，从而导致更安全和更高效的应用。未来的科学家和工程师必须掌握辐射的产量的细微差别，以便在各自领域负责任和道德地创新。