orogenic

简明释义

英[ˌɔːrəˈdʒɛnɪk]美[ˌɔːrəˈdʒɛnɪk]

adj. [地质] 造山的；造山运动的

英英释义

单词用法

同义词

反义词

例句

1.The study of volcanic rocks in orogenic belts aims mainly at retracing the tectono_magmatic evolutionary history of orogenic belts.

造山带火山岩石学研究的主要目的在于重溯造山带的构造-岩浆演化历史。

2.Sedimentary basin and adjacent orogenic belt are two basic tectonic units of continent and twins developed in a geodynamic system.

毗邻的沉积盆地与造山带是大陆构造的基本单元和形成于统一地球动力学系统中的一对孪生体。

3.The origins of orogenic belts and basins are two hot topics of current geoscience research.

造山带和盆地成因是当前地学研究的两个热点。

4.Angular unconformity belongs to an intraplate folded - orogenic deformation. Parallel unconformity is the record of intraplate epeirogenic deformation.

角度不整合是板内褶皱造山变形，平行不整合是板内造陆变形的重要记录。

5.Because a collision orogenic belt has a complicated crustal structure, new methods have to be adopted for thermal state analysis.

由于碰撞造山带具有的地壳结构的复杂性，必须采用新的研究方法来分析其热结构。

6.Altyn structural belt consists of collisional orogenic belt and thrusting strike-slip fault systems.

阿尔金构造带包括阿尔金碰撞造山带和阿尔金逆冲-走滑断裂系。

7.The Himalayas are a prime example of an orogenic 造山的 process resulting from the collision of tectonic plates.

喜马拉雅山是一个典型的造山的例子，源于构造板块的碰撞。

8.Many mountain ranges around the world were formed through orogenic 造山的 events during the Earth's history.

世界各地的许多山脉都是通过地球历史上的造山的事件形成的。

9.During the orogenic 造山的 phase, intense pressure and heat can cause metamorphism of existing rocks.

在造山的阶段，强烈的压力和热量可以导致现有岩石的变质作用。

10.Geologists study orogenic 造山的 belts to understand the formation of continental crust.

地质学家研究造山的带以了解大陆地壳的形成。

11.The orogenic 造山的 processes can lead to significant geological features such as folds and faults.

造山的过程可以导致显著的地质特征，如褶皱和断层。

作文

The term orogenic refers to the processes related to the formation of mountains, particularly through tectonic forces that cause the Earth's crust to fold and uplift. Understanding orogenic events is crucial for geologists who study the Earth’s geological history and the forces that shape its surface. The mechanisms of orogenic activity are often linked to plate tectonics, where the movement of the Earth's lithospheric plates leads to the creation of mountain ranges. For instance, the Himalayas, which are among the tallest mountains in the world, were formed as a result of the collision between the Indian and Eurasian plates. This collision not only resulted in the uplift of the land but also created a unique ecosystem that supports diverse flora and fauna.In addition to the physical formation of mountains, orogenic processes have significant implications for climate and weather patterns. Mountain ranges can act as barriers to prevailing winds, leading to varied climatic conditions on either side. For example, the presence of the Andes mountains in South America creates a rain shadow effect, where one side receives abundant rainfall while the other remains arid. This phenomenon highlights the interconnectedness of geological processes and ecological systems, demonstrating how orogenic activity can influence biodiversity and habitat distribution.Moreover, studying orogenic events can provide insights into natural resources. Many mineral deposits, such as gold, silver, and copper, are associated with mountainous regions formed by orogenic processes. As mountains erode over time, these minerals can be transported and concentrated in riverbeds and plains, making them accessible for mining. Thus, understanding the history and mechanics of orogenic activity can have economic implications as well.The study of orogenic processes also plays a vital role in assessing geological hazards. Regions that have experienced significant orogenic activity are often prone to earthquakes and landslides due to the instability of the uplifted land. For instance, the San Andreas Fault in California is a well-known example of an area where tectonic movements have led to both orogenic formations and seismic activity. By analyzing past orogenic events, scientists can better predict potential hazards and develop strategies for disaster preparedness.In conclusion, the concept of orogenic activity encompasses a wide range of geological processes that play a pivotal role in shaping the Earth’s landscape, influencing climate, and impacting human activities. From the majestic peaks of the Rockies to the rugged terrain of the Alps, the effects of orogenic processes are evident all around us. As we continue to explore and understand these phenomena, we gain valuable knowledge that can help us navigate the challenges of natural resource management, environmental conservation, and disaster risk reduction. The study of orogenic events not only enriches our understanding of the planet but also emphasizes the importance of geology in our everyday lives.

“orogenic”一词指的是与山脉形成相关的过程，特别是通过使地壳折叠和抬升的构造力量。理解orogenic事件对于研究地球地质历史及塑造其表面力量的地质学家至关重要。orogenic活动的机制通常与板块构造有关，地球的岩石圈板块的运动导致山脉的形成。例如，喜马拉雅山是世界上最高的山脉之一，正是由于印度板块与欧亚板块的碰撞而形成。这种碰撞不仅导致了土地的抬升，还创造了一个支持多样植物和动物的独特生态系统。除了山脉的物理形成外，orogenic过程对气候和天气模式也有显著影响。山脉可以作为盛行风的障碍，导致两侧气候条件的差异。例如，南美洲的安第斯山脉的存在造成了雨影效应，一侧降雨丰沛，而另一侧则干旱。这一现象突显了地质过程与生态系统之间的相互联系，展示了orogenic活动如何影响生物多样性和栖息地分布。此外，研究orogenic事件可以提供有关自然资源的见解。许多矿产资源，如金、银和铜，与由orogenic过程形成的山区相关联。随着山脉随时间侵蚀，这些矿物可以被运输并集中在河床和平原中，使其易于开采。因此，理解orogenic活动的历史和机制也可能具有经济意义。orogenic过程的研究在评估地质灾害方面也发挥着至关重要的作用。经历过显著orogenic活动的地区往往由于抬升土地的不稳定性而容易发生地震和滑坡。例如，加利福尼亚的圣安德烈亚斯断层就是一个众所周知的例子，在这里，构造运动导致了orogenic形成和地震活动。通过分析过去的orogenic事件，科学家可以更好地预测潜在的危险，并制定灾难准备的策略。总之，orogenic活动的概念涵盖了一系列对塑造地球景观、影响气候和影响人类活动起着关键作用的地质过程。从落基山脉的雄伟峰峦到阿尔卑斯山的崎岖地形，orogenic过程的影响在我们周围随处可见。随着我们继续探索和理解这些现象，我们获得了有价值的知识，可以帮助我们应对自然资源管理、环境保护和灾害风险减少的挑战。对orogenic事件的研究不仅丰富了我们对地球的理解，还强调了地质学在我们日常生活中的重要性。