gas permeability

简明释义

气体渗透率

英英释义

例句

1.The study focused on the gas permeability of various membrane materials to determine their efficiency in filtration systems.

这项研究集中于各种膜材料的气体渗透性，以确定它们在过滤系统中的效率。

2.In the context of environmental engineering, gas permeability is a key factor in designing landfill liners.

在环境工程中，气体渗透性是设计垃圾填埋场衬里的关键因素。

3.High gas permeability is crucial for the performance of fuel cells, as it affects the fuel's flow rate.

高气体渗透性对燃料电池的性能至关重要，因为它影响燃料的流速。

4.Researchers are exploring ways to enhance the gas permeability of polymers for better packaging solutions.

研究人员正在探索增强聚合物气体渗透性的方法，以便提供更好的包装解决方案。

5.The gas permeability of soil can significantly impact plant growth and water retention.

土壤的气体渗透性会显著影响植物生长和水分保持。

作文

Gas permeability is a crucial property in various fields, including material science, environmental engineering, and the oil and gas industry. It refers to the ability of a material to allow gases to pass through it. Understanding gas permeability (气体渗透性) is essential for designing materials that can effectively manage gas flow, whether it's in the context of filtration systems, packaging materials, or geological formations. In the realm of environmental engineering, gas permeability (气体渗透性) plays a significant role in assessing the movement of gases through soil and rock layers. This information is vital for predicting how pollutants may migrate through the environment and for designing effective remediation strategies. For instance, when dealing with landfill sites, understanding the gas permeability (气体渗透性) of the surrounding soil can help engineers determine how easily methane and other gases can escape into the atmosphere. In material science, researchers are continually exploring new materials with enhanced gas permeability (气体渗透性) properties. For example, polymer membranes are often engineered to have specific gas permeability (气体渗透性) characteristics to optimize their performance in applications such as gas separation and carbon capture. By manipulating the structure of these membranes at the molecular level, scientists can create materials that selectively allow certain gases to pass while blocking others, thereby improving efficiency in industrial processes. The oil and gas industry also relies heavily on the concept of gas permeability (气体渗透性). In this sector, understanding the gas permeability (气体渗透性) of reservoir rocks is critical for maximizing hydrocarbon recovery. Engineers use this information to design enhanced oil recovery techniques, which can involve injecting gases into reservoirs to increase pressure and drive more oil to the surface. The gas permeability (气体渗透性) of the rock influences how effectively these gases can move through the formation, impacting the overall success of extraction efforts. Moreover, gas permeability (气体渗透性) is not just a static property; it can change under different conditions. Factors such as temperature, pressure, and the presence of moisture can all affect a material's gas permeability (气体渗透性). Therefore, it is crucial for researchers and engineers to conduct thorough testing under varying conditions to accurately assess gas permeability (气体渗透性) and its implications for their specific applications. In conclusion, gas permeability (气体渗透性) is a fundamental property that impacts a wide range of industries and applications. From environmental protection to energy production, understanding and optimizing gas permeability (气体渗透性) is essential for advancing technology and ensuring sustainable practices. As research continues to evolve, new materials and methods will likely emerge, further enhancing our ability to control gas flow and improve efficiency across various sectors.

气体渗透性是多个领域中的一个关键属性，包括材料科学、环境工程以及石油和天然气行业。它指的是材料允许气体通过的能力。理解气体渗透性（gas permeability）对设计能够有效管理气体流动的材料至关重要，无论是在过滤系统、包装材料还是地质构造的背景下。在环境工程领域，气体渗透性（gas permeability）在评估气体通过土壤和岩层的运动方面发挥着重要作用。这些信息对于预测污染物如何在环境中迁移以及设计有效的修复策略至关重要。例如，在处理垃圾填埋场时，了解周围土壤的气体渗透性（gas permeability）可以帮助工程师确定甲烷和其他气体多容易逃逸到大气中。在材料科学中，研究人员不断探索具有增强的气体渗透性（gas permeability）特性的材料。例如，聚合物膜通常被设计成具有特定的气体渗透性（gas permeability）特征，以优化其在气体分离和碳捕集等应用中的性能。通过在分子水平上操控这些膜的结构，科学家可以创造出选择性地允许某些气体通过而阻止其他气体的材料，从而提高工业过程的效率。石油和天然气行业也严重依赖于气体渗透性（gas permeability）的概念。在这个领域，了解储层岩石的气体渗透性（gas permeability）对最大化碳氢化合物的回收至关重要。工程师利用这些信息设计增强油气回收技术，这可能涉及向储层注入气体以增加压力并推动更多的石油到达地表。岩石的气体渗透性（gas permeability）影响这些气体通过构造的有效移动，从而影响提取工作的整体成功。此外，气体渗透性（gas permeability）不仅是一个静态属性；它可以在不同条件下发生变化。温度、压力和湿气的存在等因素都可以影响材料的气体渗透性（gas permeability）。因此，研究人员和工程师进行全面测试以准确评估气体渗透性（gas permeability）及其对特定应用的影响是至关重要的。总之，气体渗透性（gas permeability）是一个基本属性，影响着多个行业和应用。从环境保护到能源生产，理解和优化气体渗透性（gas permeability）对推动技术进步和确保可持续实践至关重要。随着研究的不断发展，新的材料和方法将可能出现，进一步增强我们控制气体流动和提高各个领域效率的能力。