lateral distribution

简明释义

横向分布

英英释义

例句

1.The geologist presented findings on the lateral distribution of mineral deposits in the region, which could impact mining operations.

地质学家展示了该地区矿物沉积的横向分布发现，这可能影响采矿作业。

2.The study examined the lateral distribution of pollutants in the river, revealing significant variations in concentration across different areas.

研究考察了河流中污染物的横向分布，揭示了不同区域浓度的显著差异。

3.In the context of urban planning, understanding the lateral distribution of green spaces can help improve community health.

在城市规划中，了解绿色空间的横向分布可以帮助改善社区健康。

4.The research focused on the lateral distribution of seismic waves during the earthquake to assess damage levels.

研究集中在地震期间地震波的横向分布上，以评估损坏程度。

5.By analyzing the lateral distribution of temperature in the ocean, scientists can better understand climate change effects.

通过分析海洋中的横向分布温度，科学家可以更好地理解气候变化的影响。

作文

In the field of science and engineering, the term lateral distribution refers to the way in which a particular quantity, such as mass, energy, or force, is spread out or distributed across a lateral plane. This concept is crucial in various applications, including fluid dynamics, structural engineering, and environmental studies. Understanding lateral distribution allows researchers and engineers to predict how materials will behave under different conditions, which is essential for designing safe and efficient systems.For instance, in fluid dynamics, the lateral distribution of fluid flow can significantly affect the performance of hydraulic systems. When analyzing how water flows through a pipe, engineers must consider how the velocity and pressure of the water vary along the width of the pipe. If the lateral distribution of flow is uneven, it can lead to problems such as turbulence, increased resistance, and even pipe failure. Therefore, understanding this distribution helps in optimizing the design of piping systems to ensure smooth and efficient flow.Similarly, in structural engineering, the lateral distribution of loads on a building or bridge is critical for ensuring its stability and safety. When a structure is subjected to forces such as wind or seismic activity, these forces are not applied uniformly. Instead, they are distributed laterally across the structure. Engineers must analyze this lateral distribution to determine how much stress each part of the structure experiences. By doing so, they can reinforce specific areas to prevent failure and ensure that the structure can withstand external forces.In environmental studies, the lateral distribution of pollutants in a body of water can provide valuable insights into contamination sources and the effectiveness of remediation efforts. Researchers often use models to simulate how pollutants disperse laterally across a lake or river. This information is vital for developing strategies to clean up contaminated sites and protect ecosystems. By understanding the lateral distribution of pollutants, scientists can identify hotspots of contamination and prioritize areas for cleanup efforts.Furthermore, the concept of lateral distribution extends beyond just physical sciences. In social sciences, it can also describe how resources or opportunities are distributed across different groups or regions. For example, in urban planning, understanding the lateral distribution of public services, such as schools and hospitals, can help planners identify areas that are underserved and need additional resources. This approach ensures that all communities have equitable access to essential services, promoting social equity and improving overall quality of life.In conclusion, the concept of lateral distribution plays a significant role in various fields, from engineering to environmental science and social planning. By understanding how quantities are distributed laterally, professionals can make informed decisions that enhance the efficiency, safety, and equity of their projects. Whether it’s optimizing fluid flow in pipes, ensuring the structural integrity of buildings, or addressing environmental pollution, the principles of lateral distribution are essential for achieving successful outcomes. As we continue to face complex challenges in our world, the importance of mastering such concepts cannot be overstated, as they are fundamental to innovation and problem-solving in diverse disciplines.

在科学和工程领域，术语lateral distribution指的是某一特定量（例如质量、能量或力）在横向平面上的分布方式。这个概念在流体动力学、结构工程和环境研究等多个应用中至关重要。理解lateral distribution使研究人员和工程师能够预测材料在不同条件下的行为，这对于设计安全高效的系统至关重要。例如，在流体动力学中，流体流动的lateral distribution会显著影响液压系统的性能。当分析水在管道中的流动时，工程师必须考虑水的速度和压力如何在管道的宽度上变化。如果流动的lateral distribution不均匀，可能会导致湍流、阻力增加，甚至管道破裂。因此，理解这种分布有助于优化管道系统的设计，以确保流动的顺畅和高效。同样，在结构工程中，建筑物或桥梁上的荷载的lateral distribution对于确保其稳定性和安全性至关重要。当结构受到风或地震等外力作用时，这些力量并不是均匀施加的，而是横向分布在结构上。工程师必须分析这种lateral distribution以确定结构的每个部分承受多少应力。通过这样做，他们可以加强特定区域以防止失效，并确保结构能够承受外部力量。在环境研究中，水体中污染物的lateral distribution可以为污染来源和修复工作效果提供有价值的见解。研究人员通常使用模型来模拟污染物在湖泊或河流中的横向扩散。这些信息对于制定清理受污染场所和保护生态系统的策略至关重要。通过理解污染物的lateral distribution，科学家可以识别污染热点，并优先考虑清理工作。此外，lateral distribution的概念不仅限于自然科学。在社会科学中，它也可以描述资源或机会在不同群体或地区之间的分配。例如，在城市规划中，理解公共服务（如学校和医院）的lateral distribution可以帮助规划者识别服务不足的地区，并需要额外的资源。这种方法确保所有社区都能公平地获得基本服务，促进社会公平，提高整体生活质量。总之，lateral distribution的概念在多个领域中扮演着重要角色，从工程到环境科学和社会规划。通过理解数量的横向分布，专业人员可以做出明智的决策，从而提高项目的效率、安全性和公平性。无论是优化管道中的流体流动、确保建筑物的结构完整性，还是解决环境污染问题，lateral distribution的原则对于取得成功的结果至关重要。随着我们继续面临世界上复杂的挑战，掌握这些概念的重要性不可低估，因为它们是各个学科创新和解决问题的基础。