basement hydrocarbon reservoir

简明释义

基岩油气藏;

英英释义

例句

1.The geologists discovered a significant basement hydrocarbon reservoir 基底碳氢化合物储层 beneath the sedimentary layers.

地质学家在沉积层下发现了一个重要的基底碳氢化合物储层。

2.The basement hydrocarbon reservoir 基底碳氢化合物储层 was found to contain both oil and natural gas.

发现基底碳氢化合物储层中同时含有石油和天然气。

3.The seismic data revealed the presence of a large basement hydrocarbon reservoir 基底碳氢化合物储层 that could supply oil for decades.

地震数据揭示了一个大型的基底碳氢化合物储层的存在，这可能为未来几十年提供石油。

4.Exploration companies are increasingly investing in basement hydrocarbon reservoirs 基底碳氢化合物储层 due to their potential for high yield.

由于潜在的高产量，勘探公司越来越多地投资于基底碳氢化合物储层。

5.Engineers are designing new extraction methods for the basement hydrocarbon reservoir 基底碳氢化合物储层 to improve efficiency.

工程师正在设计新的提取方法，以提高对基底碳氢化合物储层的效率。

作文

In the field of geology and petroleum engineering, the term basement hydrocarbon reservoir refers to a significant geological formation that serves as a storage space for hydrocarbons. These reservoirs are typically found beneath sedimentary layers and are crucial for oil and gas exploration. Understanding the characteristics of a basement hydrocarbon reservoir is essential for geologists and engineers who seek to extract these valuable resources efficiently.The basement hydrocarbon reservoir is often composed of igneous or metamorphic rocks, which can provide excellent traps for hydrocarbons. The presence of natural fractures and faults within these rocks can enhance the permeability, allowing hydrocarbons to migrate and accumulate over time. This accumulation process is influenced by various geological factors, including the types of source rocks, the timing of hydrocarbon generation, and the structural evolution of the region.One of the primary reasons why the study of basement hydrocarbon reservoirs is important is due to the increasing demand for energy resources worldwide. As conventional oil and gas reserves become depleted, exploration efforts are shifting towards these basement formations, which may hold substantial untapped reserves. The challenge lies in accurately assessing the potential of these reservoirs, as they are often located at significant depths and require advanced technologies for exploration and extraction.Geophysical methods, such as seismic surveys, are commonly employed to identify potential basement hydrocarbon reservoirs. These techniques allow geologists to map the subsurface structures and determine the likelihood of hydrocarbon presence. Once a potential reservoir is identified, further drilling and testing are conducted to evaluate its viability for production.Moreover, the environmental implications of exploiting basement hydrocarbon reservoirs cannot be overlooked. The extraction process can pose risks to local ecosystems and water sources. Therefore, it is imperative that companies adhere to strict regulations and implement sustainable practices to minimize their impact on the environment.In conclusion, the concept of a basement hydrocarbon reservoir plays a pivotal role in the ongoing search for energy resources. As we continue to explore deeper geological formations, our understanding of these reservoirs will evolve, leading to more efficient extraction techniques and better environmental stewardship. The future of energy production may very well depend on our ability to harness the potential of these hidden reservoirs beneath the Earth's surface.

在地质学和石油工程领域，术语基底碳氢化合物储层指的是一个重要的地质构造，它作为碳氢化合物的储存空间。这些储层通常位于沉积层之下，对于石油和天然气的勘探至关重要。理解基底碳氢化合物储层的特征对寻求高效提取这些宝贵资源的地质学家和工程师而言是非常重要的。基底碳氢化合物储层通常由火成岩或变质岩组成，这些岩石可以为碳氢化合物提供良好的储存空间。这些岩石内自然存在的裂缝和断层可以增强其渗透性，从而使碳氢化合物随着时间的推移迁移和积聚。这一积聚过程受到多种地质因素的影响，包括源岩的类型、碳氢化合物生成的时机以及该地区的构造演变。研究基底碳氢化合物储层的重要原因之一是由于全球对能源资源日益增长的需求。随着常规石油和天然气储备的枯竭，勘探工作正逐渐转向这些基底构造，这些构造可能蕴藏着大量未开发的储量。挑战在于准确评估这些储层的潜力，因为它们通常位于较深的地层中，需要先进的技术进行勘探和开采。地球物理方法，例如地震勘测，通常用于识别潜在的基底碳氢化合物储层。这些技术使地质学家能够绘制地下结构图，并确定碳氢化合物存在的可能性。一旦识别出潜在储层，就会进行进一步的钻探和测试，以评估其生产的可行性。此外，开发基底碳氢化合物储层的环境影响也不容忽视。提取过程可能对当地生态系统和水源造成风险。因此，各公司必须遵循严格的法规，并实施可持续的做法，以尽量减少对环境的影响。总之，基底碳氢化合物储层的概念在持续寻找能源资源的过程中发挥着关键作用。随着我们继续探索更深的地质构造，我们对这些储层的理解将不断发展，从而导致更高效的提取技术和更好的环境管理。未来的能源生产可能在很大程度上依赖于我们利用这些隐藏在地球表面之下的储层的能力。