petrogenetic

简明释义

英[/ˌpɛtroʊdʒəˈnɛtɪk/]美[/ˌpɛtroʊdʒəˈnɛtɪk/]

adj. 岩石成因的

英英释义

单词用法

同义词

反义词

例句

1.Assorting and naming of volcanic rock is mainly based on the content of main petrogenetic mineral.

主要造岩矿物的含量是火山岩分类定名的主要依据。

2.The paper is devoted to the endogenous factors of chromite, platinum and sulfide ore deposit formation that accompanied specific petrogenetic processes with strong effects on ore concentration.

文章专门讨论与特定成岩作用伴生的铬、铂和硫化物矿床形成的内生因素。

3.The alkali feldspar granites studied belong to A2 on petrogenetic type, and should be formed in a post-collisional tensional environment.

这些碱长花岗岩在成因类型上属a2型，形成于后碰撞的张性环境中。

4.Finally, a positive correlation is observed between the partial fusion extent and the petrogenetic temperature and pressure.

初始熔浆部分熔融程度温度、压力呈正消长关系。

5.The paper is devoted to the endogenous factors of chromite, platinum and sulfide ore deposit formation that accompanied specific petrogenetic processes with strong effects on ore concentration.

文章专门讨论与特定成岩作用伴生的铬、铂和硫化物矿床形成的内生因素。

6.The petrogenetic 岩石生成的 characteristics of granite indicate its formation deep within the Earth's crust.

花岗岩的岩石生成的特征表明它是在地壳深处形成的。

7.Geologists often analyze petrogenetic 岩石生成的 patterns to understand the formation of mountain ranges.

地质学家常常分析岩石生成的模式，以理解山脉的形成。

8.Understanding the petrogenetic 岩石生成的 evolution of a region helps in natural resource exploration.

了解一个地区的岩石生成的演化有助于自然资源的勘探。

9.Researchers are investigating the petrogenetic 岩石生成的 links between different types of igneous rocks.

研究人员正在调查不同类型火成岩之间的岩石生成的联系。

10.The study of the petrogenetic 岩石生成的 processes can reveal the history of volcanic eruptions.

对岩石生成的过程的研究可以揭示火山喷发的历史。

作文

The study of rocks and their formation is a fundamental aspect of geology, and it encompasses a wide range of processes that contribute to the development of the Earth's crust. One of the key concepts in this field is petrogenetic, which refers to the origin and evolution of rocks. Understanding petrogenetic processes is essential for geologists as they seek to uncover the history of our planet. This term derives from the Greek words 'petra,' meaning rock, and 'genesis,' meaning origin or creation. Therefore, petrogenetic essentially pertains to how various types of rocks are formed and transformed over geological time scales.To comprehend petrogenetic processes, one must first consider the different types of rocks: igneous, sedimentary, and metamorphic. Each of these rock types has its own unique formation processes that are influenced by various environmental factors. For instance, igneous rocks form through the cooling and solidification of magma or lava, while sedimentary rocks are created from the accumulation of mineral and organic particles. Metamorphic rocks, on the other hand, arise from the alteration of existing rocks due to high temperature, pressure, or chemically active fluids.Geologists utilize the concept of petrogenetic relationships to trace the origins of rocks and to understand the geological history of a region. By studying mineral compositions and textures, scientists can infer the conditions under which a rock was formed. For example, the presence of certain minerals can indicate whether a rock originated from a volcanic eruption or from sedimentation in a body of water. This information is crucial for reconstructing past environments and understanding the tectonic processes that shape our planet.Moreover, the application of petrogenetic principles extends beyond academic research. In the field of natural resource exploration, understanding the petrogenetic history of an area can guide geologists in locating valuable minerals and fossil fuels. By analyzing the formation processes of surrounding rocks, they can identify potential sites for mining and drilling, thereby contributing to economic development.In addition to practical applications, the study of petrogenetic processes also raises important questions about the Earth's future. As we face climate change and other environmental challenges, understanding how rocks respond to these changes is critical. For instance, the weathering of rocks can influence soil formation and nutrient cycling, which are essential for sustaining ecosystems. By examining petrogenetic processes, scientists can better predict how geological systems will react to ongoing environmental shifts.In conclusion, the term petrogenetic encapsulates a vital area of study within geology that focuses on the origin and evolution of rocks. Its implications reach far beyond mere academic interest; they extend into practical applications in resource exploration and environmental science. As we continue to explore and understand the complexities of our planet, the importance of petrogenetic studies will only grow, helping us to unravel the mysteries of Earth's past and anticipate its future.

岩石及其形成的研究是地质学的一个基本方面，它涵盖了许多有助于地球地壳发展过程的范围。在这个领域的一个关键概念是petrogenetic，它指的是岩石的起源和演变。理解petrogenetic过程对于地质学家来说至关重要，因为他们试图揭示我们星球的历史。这个术语源自希腊文单词“petra”，意为岩石，以及“genesis”，意为起源或创造。因此，petrogenetic本质上涉及各种类型的岩石是如何在地质时间尺度上形成和转变的。要理解petrogenetic过程，首先必须考虑不同类型的岩石：火成岩、沉积岩和变质岩。这些岩石类型各自具有独特的形成过程，受到各种环境因素的影响。例如，火成岩是通过岩浆或熔岩的冷却和固化而形成，而沉积岩则是由矿物和有机颗粒的积累所创建的。变质岩则是由于高温、高压或化学活性流体的作用而产生的现存岩石的改造。地质学家利用petrogenetic关系来追溯岩石的起源，并理解一个地区的地质历史。通过研究矿物成分和纹理，科学家可以推断出岩石形成时的条件。例如，某些矿物的存在可以表明一块岩石是源自火山喷发还是来自水体中的沉积。这些信息对于重建过去的环境和理解塑造我们星球的构造过程至关重要。此外，petrogenetic原理的应用超越了学术研究。在自然资源勘探领域，理解一个地区的petrogenetic历史可以指导地质学家寻找有价值的矿物和化石燃料。通过分析周围岩石的形成过程，他们可以识别潜在的采矿和钻探地点，从而促进经济发展。除了实际应用外，岩石的petrogenetic过程的研究还引发了关于地球未来的重要问题。当我们面临气候变化和其他环境挑战时，理解岩石如何响应这些变化至关重要。例如，岩石的风化可以影响土壤形成和养分循环，而这些对维持生态系统至关重要。通过检查petrogenetic过程，科学家可以更好地预测地质系统如何对持续的环境变化做出反应。总之，petrogenetic这一术语概括了地质学中一个重要的研究领域，专注于岩石的起源和演变。它的影响远不止于学术兴趣；它延伸到资源勘探和环境科学等实际应用。随着我们继续探索和理解我们星球的复杂性，petrogenetic研究的重要性只会增加，帮助我们揭开地球过去的神秘面纱，并预测其未来。