available pore space

简明释义

有效孔隙空间;

英英释义

例句

1.In geology, understanding the available pore space can help predict how easily fluids can move through rock formations.

在地质学中，理解可用孔隙空间可以帮助预测流体在岩层中的流动容易程度。

2.Researchers measured the available pore space in the sediment to assess its capacity for storing contaminants.

研究人员测量了沉积物中的可用孔隙空间以评估其存储污染物的能力。

3.The construction of the building was delayed due to insufficient available pore space for drainage.

由于排水的可用孔隙空间不足，建筑施工被延迟。

4.The effectiveness of the filtration system relies on the available pore space in the filter media.

过滤系统的有效性依赖于过滤介质中的可用孔隙空间。

5.The soil's ability to retain water depends largely on the amount of available pore space.

土壤保持水分的能力在很大程度上取决于可用孔隙空间的数量。

作文

The concept of available pore space is crucial in various fields, particularly in geology, hydrology, and environmental science. Understanding this term can significantly enhance our knowledge about how water, air, and nutrients move through soil and rock formations. In simple terms, available pore space refers to the voids or spaces within a material that can be filled with fluids, such as water or air. This property is vital for several reasons, including groundwater movement, plant growth, and the overall health of ecosystems.In geology, the available pore space of rocks determines how much water they can store. For instance, sandstone typically has a high available pore space, allowing it to hold significant amounts of water, which can be crucial for aquifers. Conversely, igneous rocks like granite have very low available pore space, making them less effective for storing groundwater. This variation in available pore space among different rock types influences water supply availability for communities and ecosystems.In agricultural practices, understanding the available pore space in soil is essential for optimizing crop production. Soils with adequate available pore space can retain moisture and provide necessary aeration for roots. If the available pore space is too low, plants may suffer from water stress, leading to reduced yields. Farmers often assess the available pore space in their fields to determine the best irrigation practices and soil amendments needed to improve productivity.Moreover, the available pore space plays a significant role in environmental sustainability. As urbanization increases, natural landscapes are replaced with impervious surfaces, reducing the available pore space for water infiltration. This alteration can lead to increased runoff, flooding, and decreased groundwater recharge. Therefore, understanding and managing the available pore space in urban planning is critical for maintaining healthy water cycles and preventing environmental degradation.In summary, the term available pore space encompasses a fundamental aspect of how materials interact with fluids. Its implications reach far beyond geology and agriculture, affecting water resources, ecosystem health, and urban development. By studying and managing the available pore space, we can better understand and address the challenges related to water management, food security, and environmental conservation. As we continue to face global challenges such as climate change and population growth, the importance of available pore space will only become more pronounced in our efforts to create sustainable solutions for future generations.

“可用孔隙空间”这一概念在多个领域中至关重要，尤其是在地质学、水文学和环境科学中。理解这个术语可以显著增强我们对水、空气和养分如何在土壤和岩石形成中移动的认识。简单来说，“可用孔隙空间”是指材料内部可以被液体（如水或空气）填充的空隙或空间。这一特性对于多个原因至关重要，包括地下水流动、植物生长以及生态系统的整体健康。在地质学中，岩石的“可用孔隙空间”决定了它们能储存多少水。例如，砂岩通常具有较高的“可用孔隙空间”，使其能够储存大量水，这对含水层至关重要。相反，花岗岩等火成岩的“可用孔隙空间”非常低，使其在储存地下水方面效果较差。这种不同岩石类型之间的“可用孔隙空间”的变化影响着社区和生态系统的水供应可用性。在农业实践中，理解土壤中的“可用孔隙空间”对于优化作物生产至关重要。具有足够“可用孔隙空间”的土壤可以保持水分并为根系提供必要的通气。如果“可用孔隙空间”过低，植物可能会遭受水分压力，从而导致产量减少。农民通常评估他们田地中的“可用孔隙空间”，以确定最佳的灌溉实践和改善生产力所需的土壤改良措施。此外，“可用孔隙空间”在环境可持续性中也起着重要作用。随着城市化的增加，自然景观被不透水表面取代，减少了水分渗透的“可用孔隙空间”。这种变化可能导致径流增加、洪水和地下水补给减少。因此，在城市规划中理解和管理“可用孔隙空间”对于维持健康的水循环和防止环境退化至关重要。总之，术语“可用孔隙空间”涵盖了材料与流体相互作用的基本方面。它的影响远不止于地质学和农业，还影响着水资源、生态系统健康和城市发展。通过研究和管理“可用孔隙空间”，我们可以更好地理解和应对与水管理、粮食安全和环境保护相关的挑战。随着我们继续面临气候变化和人口增长等全球挑战，“可用孔隙空间”的重要性将在我们为未来世代创造可持续解决方案的努力中变得更加明显。