angle of scattering

简明释义

散射角;

英英释义

例句

1.The scientists adjusted the laser to change the angle of scattering 散射角 for better measurement accuracy.

科学家调整激光以改变散射角 angle of scattering以提高测量精度。

2.The angle of scattering 散射角 was found to be critical in understanding how light interacts with different surfaces.

发现散射角 angle of scattering在理解光如何与不同表面相互作用中至关重要。

3.In particle physics, the angle of scattering 散射角 can reveal information about the forces at play during collisions.

在粒子物理学中，散射角 angle of scattering可以揭示碰撞过程中作用力的信息。

4.By analyzing the angle of scattering 散射角, researchers can infer the properties of the material being tested.

通过分析散射角 angle of scattering，研究人员可以推断被测试材料的特性。

5.The experiment measured the angle of scattering 散射角 to determine the size of the particles in the solution.

实验测量了散射角 angle of scattering以确定溶液中颗粒的大小。

作文

In the realm of physics and optics, the term angle of scattering refers to the angle at which particles or waves deviate from their original path after interacting with a medium or an obstacle. This concept is crucial in various scientific fields, including meteorology, astronomy, and materials science. Understanding the angle of scattering can provide insights into the properties of materials, the behavior of light, and even the dynamics of atmospheric phenomena.When light encounters a particle, it can be absorbed, transmitted, or scattered. The angle of scattering specifically describes the direction in which the light is redirected as a result of this interaction. For instance, when sunlight passes through the atmosphere, it interacts with air molecules and small particles, leading to various scattering effects that give rise to the blue color of the sky. The angle of scattering plays a significant role in determining how much light reaches our eyes and from what direction.In practical applications, the angle of scattering is vital for technologies such as radar and lidar, which rely on the scattering of electromagnetic waves to detect objects and measure distances. By analyzing the angle of scattering of returned signals, scientists and engineers can infer information about the size, shape, and composition of the targets being studied. This principle is also applied in medical imaging techniques, such as ultrasound, where the scattering of sound waves provides valuable data about tissues and organs.Moreover, the angle of scattering is not limited to light; it also applies to other types of waves, including sound and even seismic waves. In geophysics, understanding the angle of scattering of seismic waves can help scientists locate and characterize underground structures, such as oil reservoirs or fault lines. This information is crucial for resource exploration and earthquake analysis.In conclusion, the concept of angle of scattering is fundamental to our understanding of wave interactions in various scientific disciplines. Whether it is light scattering in the atmosphere, electromagnetic wave detection in radar systems, or sound wave analysis in medical imaging, the angle of scattering provides essential information that helps us comprehend the world around us. As technology advances and our understanding of these interactions deepens, the importance of the angle of scattering will continue to grow, influencing both scientific research and practical applications in everyday life.

在物理学和光学领域，短语散射角指的是粒子或波在与介质或障碍物相互作用后，从其原始路径偏离的角度。这个概念在气象学、天文学和材料科学等多个科学领域中至关重要。理解散射角可以提供关于材料特性、光行为甚至大气现象动态的见解。当光遇到一个粒子时，它可能会被吸收、透射或散射。散射角特别描述了光在这种相互作用后被重新定向的方向。例如，当阳光穿过大气时，它与空气分子和小颗粒相互作用，导致各种散射效应，产生天空的蓝色。散射角在决定多少光线到达我们的眼睛以及来自哪个方向方面起着重要作用。在实际应用中，散射角对于雷达和激光雷达等技术至关重要，这些技术依赖电磁波的散射来检测物体和测量距离。通过分析返回信号的散射角，科学家和工程师可以推断出被研究目标的大小、形状和成分。这一原理也应用于医学成像技术，如超声波，其中声波的散射提供有关组织和器官的宝贵数据。此外，散射角不仅限于光；它也适用于其他类型的波，包括声波甚至地震波。在地球物理学中，理解地震波的散射角可以帮助科学家定位和表征地下结构，例如油藏或断层线。这些信息对于资源勘探和地震分析至关重要。总之，散射角的概念是我们理解各种科学学科中波相互作用的基础。无论是大气中的光散射、电磁波在雷达系统中的检测，还是医学成像中的声波分析，散射角提供了帮助我们理解周围世界的重要信息。随着技术的进步和我们对这些相互作用的理解加深，散射角的重要性将继续增长，影响着科学研究和日常生活中的实际应用。