particle fluence

简明释义

粒子笼分通量

英英释义

例句

1.The particle fluence 粒子通量 was calculated to determine the exposure levels for safety protocols.

计算了particle fluence 粒子通量以确定安全协议的暴露水平。

2.Researchers found that increasing the particle fluence 粒子通量 led to more significant damage in the silicon wafers.

研究人员发现，增加particle fluence 粒子通量会导致硅晶圆受到更严重的损坏。

3.During the test, the particle fluence 粒子通量 was recorded at various depths in the target material.

在测试过程中，记录了目标材料不同深度的particle fluence 粒子通量。

4.In high-energy physics, understanding particle fluence 粒子通量 is crucial for designing detectors.

在高能物理学中，理解particle fluence 粒子通量对设计探测器至关重要。

5.The experiment measured the particle fluence 粒子通量 in the radiation field to assess its impact on the materials.

实验测量了辐射场中的particle fluence 粒子通量，以评估其对材料的影响。

作文

In the field of physics and engineering, particularly in radiation studies, the concept of particle fluence plays a crucial role. Particle fluence is defined as the number of particles passing through a unit area, typically expressed in particles per square centimeter. This measurement is essential for understanding the effects of radiation on materials and living organisms. For instance, when designing radiation shielding for medical or industrial applications, knowing the particle fluence helps engineers calculate the necessary thickness and composition of protective barriers.The significance of particle fluence extends beyond engineering; it is also vital in fields like astrophysics and nuclear physics. In astrophysics, cosmic rays bombard the Earth, and scientists measure the particle fluence to assess the potential risks these high-energy particles pose to satellites and astronauts in space. Similarly, in nuclear physics, experiments involving particle accelerators require precise calculations of particle fluence to ensure accurate results and safety protocols.Moreover, the biological impact of radiation is closely linked to particle fluence. When studying the effects of radiation on human health, researchers consider the particle fluence to determine the dose received by tissues. This understanding is critical in medical treatments such as radiation therapy for cancer patients, where the goal is to maximize damage to cancer cells while minimizing harm to surrounding healthy tissue. The relationship between particle fluence and biological effects underlines the importance of this measurement in both research and clinical settings.Furthermore, advancements in technology have led to more sophisticated methods of measuring particle fluence. Detectors and sensors can now provide real-time data on particle interactions, enabling scientists to monitor environments with high radiation levels. This capability is particularly important in nuclear power plants, where maintaining safety standards is paramount. By continuously measuring particle fluence, operators can respond promptly to any anomalies, ensuring the safety of both workers and the public.In conclusion, particle fluence is a fundamental concept that finds application across various scientific disciplines. Its relevance in engineering, astrophysics, nuclear physics, and medicine highlights its importance in understanding and managing the effects of radiation. As technology continues to evolve, the methods for measuring particle fluence will likely improve, leading to better safety protocols and enhanced knowledge of radiation interactions. By comprehending the implications of particle fluence, researchers and professionals can work towards safer environments and more effective applications of radiation in science and medicine.

在物理和工程领域，特别是在辐射研究中，粒子通量的概念起着至关重要的作用。粒子通量被定义为通过单位面积的粒子数量，通常以每平方厘米的粒子数表示。这一测量对于理解辐射对材料和生物体的影响至关重要。例如，在设计医疗或工业应用的辐射屏蔽时，了解粒子通量帮助工程师计算保护屏障所需的厚度和成分。粒子通量的重要性超越了工程领域；它在天体物理学和核物理学等领域同样至关重要。在天体物理学中，宇宙射线轰击地球，科学家测量粒子通量以评估这些高能粒子对卫星和宇航员在太空中可能造成的风险。同样，在核物理学中，涉及粒子加速器的实验需要精确计算粒子通量以确保结果的准确性和安全协议。此外，辐射对生物的影响与粒子通量密切相关。在研究辐射对人类健康的影响时，研究人员考虑粒子通量以确定组织接收到的剂量。这种理解在放射治疗癌症患者的医学治疗中至关重要，其目标是最大限度地损伤癌细胞，同时最小化对周围健康组织的伤害。粒子通量与生物效应之间的关系强调了这一测量在研究和临床环境中的重要性。此外，技术的进步使得测量粒子通量的方法更加复杂。探测器和传感器现在能够提供实时的粒子相互作用数据，使科学家能够监测高辐射水平的环境。这种能力在核电站中特别重要，维护安全标准至关重要。通过持续测量粒子通量，操作人员可以及时响应任何异常，确保工人和公众的安全。总之，粒子通量是一个基本概念，广泛应用于各个科学学科。它在工程、天体物理、核物理和医学中的相关性突显了其在理解和管理辐射影响方面的重要性。随着技术的不断发展，测量粒子通量的方法可能会得到改善，从而导致更好的安全协议和对辐射相互作用的深入了解。通过理解粒子通量的含义，研究人员和专业人士可以朝着更安全的环境和更有效的辐射应用努力。