lithologic

简明释义

英[ˌlɪθəˈlɑdʒɪk]美[ˌlɪθəˈlɑdʒɪk]

adj. 岩性的

英英释义

单词用法

同义词

反义词

例句

1.The reservoir boundary includes oil-water contact, lithologic boundary and fault limit.

油藏边界主要包括油水界面、岩性边界和断层边界等。

2.Secondary lithologic trap is the object of potential seeking of Songliao Basin in high maturity stage.

次生岩性圈闭是松辽盆地进入高成熟期后挖掘潜力的对象。

3.Erlian Basin boasts the good formation conditions for lithologic and stratigraphic oil reservoirs.

二连盆地具有形成岩性、地层油藏的良好条件。

4.The theory model computing results show that the lithologic constrained inversion is an accurate and efficient method.

理论模型计算结果说明了岩性约束反演的可行性和正确性。

5.For lithologic and stratigraphic traps, their origination might relate to sea level changes and folding.

岩性圈闭和地层圈闭的形成与海平面变化和褶皱运动有关。

6.P layer in G oilfield is a structural-lithologic reservoir controlled chiefly by lithology with many oil-water layers.

油田P油层是主要受岩性控制的构造-岩性油藏，油水同层比较发育。

7.With the advance of hydrocarbon exploration, the stratigraphic and lithologic oil reservoirs are becoming important play targets.

随着油气勘探的进展，地层岩性油气藏是重要的勘探目标。

8.The geologist analyzed the lithologic 岩石学的 characteristics of the rock samples collected from the site.

地质学家分析了从现场收集的岩石样本的岩石学的特征。

9.Understanding the lithologic 岩石学的 composition is crucial for determining the area's geological history.

理解该地区的岩石学的成分对于确定该地区的地质历史至关重要。

10.The lithologic 岩石学的 map revealed a variety of sediment types in the region.

该岩石学的地图揭示了该地区多种沉积物类型。

11.Researchers conducted a lithologic 岩石学的 study to assess the potential for mineral extraction.

研究人员进行了岩石学的研究，以评估矿物提取的潜力。

12.The lithologic 岩石学的 features of the mountain range were documented in detail.

该山脉的岩石学的特征被详细记录。

作文

The study of geology encompasses various aspects of the Earth's structure, composition, and processes. One of the fundamental components of this field is the examination of rocks and their characteristics. This brings us to the term lithologic, which refers to the physical and chemical characteristics of rocks. Understanding lithologic properties is crucial for geologists as it helps them identify rock types and their origins, which in turn can provide insights into the geological history of an area. Rocks are classified into three main categories: igneous, sedimentary, and metamorphic. Each of these categories has distinct lithologic features that reflect their formation processes. For instance, igneous rocks, formed from cooled magma or lava, typically exhibit a crystalline texture with minerals arranged in a specific pattern. In contrast, sedimentary rocks are often layered and may contain fossils, indicating their formation from accumulated sediments over time. Metamorphic rocks, on the other hand, display altered lithologic characteristics due to pressure and temperature changes that transform existing rocks into new forms. The importance of lithologic analysis extends beyond academic interest; it has practical applications in fields such as natural resource management, environmental science, and civil engineering. For example, understanding the lithologic composition of an area can guide the extraction of minerals and fossil fuels, ensuring that such activities are conducted sustainably and responsibly. Additionally, knowledge of lithologic properties is vital when constructing buildings and infrastructure, as different rock types have varying strengths and weaknesses. Engineers must consider these factors to ensure the stability and safety of their projects. Moreover, lithologic studies can also play a significant role in understanding natural hazards. Areas prone to earthquakes, landslides, or volcanic activity often have specific lithologic features that can be analyzed to predict potential risks. By examining the lithologic characteristics of rocks in these regions, scientists can better assess the likelihood of such events occurring and develop strategies to mitigate their impacts on communities. In summary, the term lithologic encapsulates a vital aspect of geological study, focusing on the physical and chemical properties of rocks. It serves as a key to unlocking the mysteries of the Earth's past and understanding its present dynamics. The implications of lithologic research extend into various practical domains, highlighting the interconnectedness of geological science with real-world applications. As we continue to explore and study our planet, the significance of lithologic properties will undoubtedly remain a cornerstone of geological inquiry and environmental stewardship.

地质学的研究涵盖了地球结构、成分和过程的各个方面。这个领域的一个基本组成部分是对岩石及其特征的检查。这就引出了术语lithologic，指的是岩石的物理和化学特征。理解lithologic特性对于地质学家至关重要，因为它帮助他们识别岩石类型及其起源，从而为了解某一地区的地质历史提供见解。 岩石被分为三大类：火成岩、沉积岩和变质岩。每种类别都有独特的lithologic特征，反映了它们的形成过程。例如，火成岩是由冷却的岩浆或熔岩形成的，通常表现出晶体纹理，矿物以特定的模式排列。相比之下，沉积岩通常呈现层状，并可能包含化石，表明它们是由随时间积累的沉积物形成的。变质岩则由于压力和温度变化而显示出改变的lithologic特征，将现有岩石转变为新的形式。 lithologic分析的重要性不仅限于学术兴趣；它在自然资源管理、环境科学和土木工程等领域具有实际应用。例如，了解某一地区的lithologic组成可以指导矿物和化石燃料的开采，确保这些活动以可持续和负责任的方式进行。此外，了解lithologic特性在建筑和基础设施建设中至关重要，因为不同的岩石类型具有不同的强度和弱点。工程师必须考虑这些因素，以确保他们项目的稳定性和安全性。 此外，lithologic研究还可以在理解自然灾害方面发挥重要作用。易发生地震、滑坡或火山活动的地区往往具有特定的lithologic特征，可以分析这些特征以预测潜在风险。通过检查这些地区岩石的lithologic特性，科学家可以更好地评估此类事件发生的可能性，并制定减轻其对社区影响的策略。 总之，术语lithologic概括了地质研究的一个重要方面，关注岩石的物理和化学特性。它作为揭示地球过去奥秘和理解其当前动态的关键。lithologic研究的影响延伸到多个实际领域，突显了地质科学与现实世界应用之间的相互联系。随着我们继续探索和研究我们的星球，lithologic特性的意义无疑将继续成为地质探究和环境管理的基石。