geohydrology

简明释义

英[ˌdʒiːəʊhaɪˈdrɒlədʒi]美[ˌdʒiːoʊhaɪˈdrɑːlədʒi]

n. [地质] 地下水文学

英英释义

单词用法

同义词

反义词

例句

1.By introducing the micro change of water level, its forming condition and forming reasons, the author tries to research the geohydrology and mining technical conditions of the ore field.

通过介绍水位微动变化及其形成条件、产生原因等，试图从另一侧面认识和研究矿区水文地质条件、矿床开采技术条件等。

2.By introducing the micro change of water level, its forming condition and forming reasons, the author tries to research the geohydrology and mining technical conditions of the ore field.

通过介绍水位微动变化及其形成条件、产生原因等，试图从另一侧面认识和研究矿区水文地质条件、矿床开采技术条件等。

3.The subject matter was subdivided into geohydrology and hydrogeology.

这一主题被分为水文地质学和地质水文学。

4.The study of geohydrology 地质水文学 is essential for managing groundwater resources.

对地质水文学的研究对于管理地下水资源至关重要。

5.Understanding geohydrology 地质水文学 helps in predicting the movement of contaminants in aquifers.

理解地质水文学有助于预测污染物在含水层中的移动。

6.Researchers specializing in geohydrology 地质水文学 often work with environmental engineers.

专注于地质水文学的研究人员通常与环境工程师合作。

7.The principles of geohydrology 地质水文学 are applied in water resource management.

在水资源管理中应用了地质水文学的原理。

8.A thorough understanding of geohydrology 地质水文学 is crucial for sustainable development.

对地质水文学的透彻理解对可持续发展至关重要。

作文

Geohydrology, often referred to as the study of groundwater and its interactions with the geological environment, plays a crucial role in understanding our planet's water resources. This interdisciplinary field combines elements of geology, hydrology, and environmental science, making it essential for addressing many modern challenges related to water management and sustainability. As the global population continues to grow, the demand for clean water increases, highlighting the importance of studying geohydrology (地下水文地质学) to ensure that we can manage our water resources effectively. One of the primary focuses of geohydrology (地下水文地质学) is the movement of groundwater through various geological formations. Groundwater is a vital source of drinking water for millions of people worldwide, and understanding how it flows through aquifers is essential for maintaining this resource. Aquifers are underground layers of water-bearing rock or sediment that store significant amounts of water. By studying the properties of these formations, geohydrologists can predict how water will move within them, which is critical for both water supply and contamination prevention. In addition to groundwater movement, geohydrology (地下水文地质学) also examines the interactions between groundwater and surface water bodies, such as rivers and lakes. These interactions can significantly impact water quality and availability. For instance, when groundwater levels drop due to over-extraction, nearby rivers may experience reduced flow, affecting ecosystems and human activities dependent on those water sources. Understanding these dynamics is essential for developing sustainable water management practices that balance human needs with environmental health. Moreover, geohydrology (地下水文地质学) is vital in addressing issues related to pollution. Contaminants can easily infiltrate groundwater systems, posing risks to public health and the environment. Geohydrologists work to identify sources of contamination, assess the extent of pollution, and develop strategies for remediation. This is particularly important in agricultural areas where fertilizers and pesticides can leach into groundwater, necessitating careful monitoring and management to protect water quality. Climate change is another critical factor influencing geohydrology (地下水文地质学). Changes in precipitation patterns, increased evaporation rates, and rising temperatures can all affect groundwater recharge rates and availability. Geohydrologists study these impacts to help communities adapt to changing conditions and develop strategies for sustainable water use in the face of climate variability. This includes implementing practices such as rainwater harvesting and improved irrigation techniques to enhance water conservation efforts. In conclusion, geohydrology (地下水文地质学) is an essential field of study that provides valuable insights into groundwater resources and their interactions with the environment. As we face increasing challenges related to water scarcity, pollution, and climate change, understanding the principles of geohydrology (地下水文地质学) becomes ever more critical. By integrating knowledge from various disciplines, geohydrologists play a vital role in ensuring sustainable water management practices that benefit both people and the planet. The future of our water resources depends on our ability to understand and apply the principles of geohydrology (地下水文地质学) effectively.

地下水文地质学，通常被称为地下水及其与地质环境相互作用的研究，在理解我们星球的水资源方面发挥着至关重要的作用。这个跨学科领域结合了地质学、水文学和环境科学的元素，对于解决许多与水管理和可持续性相关的现代挑战至关重要。随着全球人口的不断增长，对清洁水的需求也在增加，这突显了研究geohydrology（地下水文地质学）以确保我们能够有效管理水资源的重要性。 geohydrology（地下水文地质学）的一个主要关注点是地下水在各种地质构造中的运动。地下水是全球数百万人民饮用水的重要来源，了解它如何在含水层中流动对于维护这一资源至关重要。含水层是地下水承载岩石或沉积物的层，储存着大量的水。通过研究这些构造的特性，地下水文地质学家可以预测水在其中的运动，这对水供应和污染预防都是至关重要的。 除了地下水运动之外，geohydrology（地下水文地质学）还研究地下水与河流、湖泊等地表水体之间的相互作用。这些相互作用可能会显著影响水质和可用性。例如，当由于过度抽取而导致地下水位下降时，附近的河流可能会经历流量减少，从而影响依赖这些水源的生态系统和人类活动。理解这些动态对于制定可持续的水管理实践至关重要，以平衡人类需求与环境健康。 此外，geohydrology（地下水文地质学）在解决与污染相关的问题方面也至关重要。污染物可以轻易渗入地下水系统，给公共健康和环境带来风险。地下水文地质学家努力识别污染源，评估污染范围，并制定修复策略。这在农业地区尤其重要，因为肥料和农药可能渗入地下水，因此需要仔细监测和管理以保护水质。 气候变化是影响geohydrology（地下水文地质学）的另一个关键因素。降水模式的变化、蒸发率的增加和气温上升都可能影响地下水补给率和可用性。地下水文地质学家研究这些影响，以帮助社区适应变化的条件，并制定应对气候变异的可持续水利用策略。这包括实施雨水收集和改进灌溉技术等实践，以增强水资源保护工作。 总之，geohydrology（地下水文地质学）是一个重要的研究领域，为地下水资源及其与环境的相互作用提供了宝贵的见解。随着我们面临与水资源短缺、污染和气候变化相关的日益严峻的挑战，理解geohydrology（地下水文地质学）的原则变得愈发重要。通过整合来自各个学科的知识，地下水文地质学家在确保有利于人类和地球的可持续水管理实践中发挥着重要作用。我们水资源的未来依赖于我们有效理解和应用geohydrology（地下水文地质学）原则的能力。