aqueous fracturing fluid

简明释义

水基压裂液;

英英释义

例句

1.During the drilling process, aqueous fracturing fluid is injected into the well to create fractures.

在钻井过程中，水基压裂液被注入井中以形成裂缝。

2.Engineers are studying the effectiveness of aqueous fracturing fluid in various geological formations.

工程师们正在研究水基压裂液在不同地质构造中的有效性。

3.The environmental impact of aqueous fracturing fluid is a major concern among activists.

环境活动人士对水基压裂液的环境影响表示担忧。

4.The oil company decided to use aqueous fracturing fluid to enhance the extraction process.

这家石油公司决定使用水基压裂液来增强提取过程。

5.The composition of aqueous fracturing fluid can vary depending on the specific requirements of the site.

根据现场的具体要求，水基压裂液的成分可能会有所不同。

作文

In recent years, the demand for energy has surged, leading to the exploration of various methods to extract natural resources more efficiently. One of the most significant advancements in this field is the use of aqueous fracturing fluid, a crucial component in hydraulic fracturing, commonly known as fracking. This technique involves injecting a mixture of water, sand, and chemicals into underground rock formations to create fractures, allowing oil and gas to flow more freely to the surface. Understanding the role of aqueous fracturing fluid is essential for comprehending the broader implications of hydraulic fracturing on both the environment and energy production.The composition of aqueous fracturing fluid typically includes around 90% water, which serves as the primary solvent. The remaining components usually consist of proppants, such as sand, and various chemical additives designed to improve the efficiency of the fracturing process. These additives can serve multiple purposes, including reducing friction, preventing bacterial growth, and stabilizing the formation. While the exact formulation can vary depending on the geological conditions and specific objectives of the operation, the core principle remains the same: to facilitate the extraction of hydrocarbons from deep within the earth.One of the key advantages of using aqueous fracturing fluid is its ability to enhance the permeability of rock formations. By creating fractures, this fluid allows for increased movement of oil and gas, which can significantly boost production rates. However, this process is not without its challenges. The environmental impact of hydraulic fracturing has been a topic of heated debate, particularly concerning the potential contamination of groundwater sources. Critics argue that the chemicals used in aqueous fracturing fluid could pose risks to drinking water supplies if they were to leak into aquifers. As a result, strict regulations and monitoring practices have been implemented in many regions to mitigate these risks.Moreover, the sustainability of using aqueous fracturing fluid raises important questions about our long-term energy strategy. While fracking has enabled countries to become more energy independent and reduce reliance on foreign oil, it also presents challenges related to water usage and disposal of wastewater. The process requires substantial amounts of water, which can strain local resources, especially in arid regions. Additionally, the disposal of used aqueous fracturing fluid can lead to environmental concerns if not managed properly.In conclusion, the use of aqueous fracturing fluid in hydraulic fracturing is a double-edged sword. On one hand, it offers a viable solution to meet the growing energy demands of our society, unlocking previously inaccessible fossil fuel reserves. On the other hand, it necessitates careful consideration of environmental impacts and resource management. As technology advances and our understanding of these processes deepens, it is crucial for policymakers, industry leaders, and the public to engage in informed discussions about the future of energy production and the role of aqueous fracturing fluid within it. Balancing economic benefits with ecological stewardship will be essential for ensuring a sustainable energy future.

近年来，能源需求激增，导致探索各种更有效地提取自然资源的方法。其中最重要的进展之一是使用水基压裂液，这是水力压裂（通常称为压裂）中的关键组成部分。这种技术涉及将水、沙子和化学品的混合物注入地下岩层，以产生裂缝，从而使石油和天然气能够更自由地流向地表。理解水基压裂液的作用对于理解水力压裂对环境和能源生产的更广泛影响至关重要。水基压裂液的组成通常包括约90%的水，水作为主要溶剂。剩余的成分通常由支撑剂（如沙子）和各种化学添加剂组成，这些添加剂旨在提高压裂过程的效率。这些添加剂可以有多种用途，包括减少摩擦、抑制细菌生长和稳定地层。尽管确切的配方可能因地质条件和操作的具体目标而异，但核心原则保持不变：促进从地下深处提取烃。使用水基压裂液的一个关键优势是其增强岩层渗透性的能力。通过创建裂缝，这种液体允许石油和天然气的运动增加，这可以显著提高生产率。然而，这一过程并非没有挑战。水力压裂的环境影响一直是激烈辩论的话题，特别是关于潜在的地下水源污染。批评者认为，水基压裂液中使用的化学物质如果渗漏到含水层中，可能会对饮用水供应构成风险。因此，在许多地区已实施严格的监管和监测措施，以减轻这些风险。此外，使用水基压裂液的可持续性也提出了有关我们长期能源战略的重要问题。虽然压裂使得国家能够更加独立于能源，减少对外国石油的依赖，但它也带来了与水资源使用和废水处置相关的挑战。该过程需要大量的水，这可能会给当地资源带来压力，尤其是在干旱地区。此外，如果处理不当，使用过的水基压裂液的处置可能会导致环境问题。总之，在水力压裂中使用水基压裂液是一把双刃剑。一方面，它为满足我们社会日益增长的能源需求提供了一种可行的解决方案，解锁了以前无法接触的化石燃料储备。另一方面，它需要仔细考虑环境影响和资源管理。随着技术的进步和我们对这些过程的理解加深，政策制定者、行业领袖和公众必须参与关于能源生产未来及水基压裂液在其中角色的知情讨论。在确保可持续能源未来方面，平衡经济利益与生态保护至关重要。