metallogenic

简明释义

英[ˌmɛtəˈlɑdʒənɪk]美[ˌmɛtəˈlɑdʒənɪk]

adj. 成矿的

英英释义

单词用法

同义词

反义词

例句

1.As a result, metallogenic systems are typical complex ones.

因此，成矿系统是典型的复杂系统。

2.Faults and magmatic rocks are two important metallogenic conditions.

断裂和岩浆岩是两大重要的成矿地质条件。

3.Among them the precambrian and cenozoic eras are the main metallogenic epoches in the world.

就全球而言，前寒武纪和新生代是金矿的重要成矿期。

4.The Duobaoshan-Kuanhe metallogenic belt is abundant in copper and gold resources.

黑龙江省多宝山-宽河成矿带铜金矿产十分丰富。

5.The fluid conduction system is an important component part of the metallogenic research.

流体输导系统是成矿研究中的一个重要内容。

6.On the basis of comprehensive analysis of the regional metallogenic condition, the metallogenic regulation in the study area is summed up.

在区域成矿地质背景、成矿地质条件综合分析的基础上，总结了区域上的成矿规律。

7.On the basis of above analyses, the metallogenic model of this type of deposit is established.

在上述分析的基础上，建立了该类型矿床的成矿模式。

8.The predication theories include of similar analogy, ore deposit model, geo-anomaly, deposit metallogenic series and metallogenic system.

预测理论有相似类比理论、矿床模型理论以及地质异常理论、成矿系列和成矿系统理论等。

9.The metallogenic setting at Xiongwu area is summarized, and the uranium metallogenic feature and condition are emphatically treated upon.

简述了雄武地区成矿地质背景，重点论述了铀成矿特征及成矿条件。

10.The geologists studied the metallogenic 成矿的 processes that lead to the formation of mineral deposits.

地质学家研究了导致矿床形成的metallogenic 成矿的 过程。

11.Understanding the metallogenic 成矿的 history of an area can help in exploration for new resources.

了解一个地区的metallogenic 成矿的 历史可以帮助寻找新的资源。

12.They conducted a metallogenic 成矿的 analysis to identify potential mining sites.

他们进行了metallogenic 成矿的 分析，以识别潜在的采矿地点。

13.The research focused on the metallogenic 成矿的 features of volcanic regions.

研究集中在火山地区的metallogenic 成矿的 特征上。

14.A detailed metallogenic 成矿的 study was necessary before starting the mining operation.

在开始采矿作业之前，进行详细的metallogenic 成矿的 研究是必要的。

作文

The study of geology encompasses various subfields, one of which is the understanding of mineral deposits. Among these, the term metallogenic refers to the processes and conditions that lead to the formation of metallic ore deposits. This concept is crucial for geologists and mining engineers, as it helps them identify areas with high potential for mining valuable metals. The metallogenic processes are influenced by a myriad of factors, including tectonic activity, magma composition, and the presence of hydrothermal fluids. Understanding the metallogenic characteristics of an area can significantly impact economic decisions related to mining. For instance, regions with a history of volcanic activity often exhibit rich metallogenic traits due to the circulation of hot fluids that can leach metals from surrounding rocks and concentrate them in certain areas. This phenomenon is particularly evident in places like the Andes mountains, where the geological history has created numerous deposits of copper, gold, and silver. Moreover, the metallogenic classification of ore deposits aids in predicting where new discoveries might be made. By studying existing deposits and their metallogenic features, geologists can develop models that suggest similar conditions elsewhere. This predictive capability is vital for sustainable resource management, ensuring that we can meet industrial demands without depleting resources excessively. In addition to economic implications, understanding metallogenic processes also plays a significant role in environmental considerations. Mining activities can lead to habitat destruction, water pollution, and other ecological impacts. By identifying metallogenic zones, companies can minimize their environmental footprint by targeting specific areas for extraction rather than indiscriminately mining large regions. Furthermore, the exploration of metallogenic provinces contributes to our knowledge of Earth's history. Each deposit tells a story of geological processes over millions of years. For example, the formation of the massive iron ore deposits in the Pilbara region of Australia is linked to ancient oceanic conditions and biological processes. Understanding these metallogenic histories not only enriches our scientific knowledge but also informs future explorations. In conclusion, the term metallogenic encapsulates the intricate relationship between geology and economic resource management. It highlights the importance of understanding how metallic ores form and where they can be found. As we continue to explore and exploit these natural resources, a comprehensive grasp of metallogenic processes will be essential for sustainable practices and responsible stewardship of the Earth’s resources. The ongoing research in this field promises to unveil more about our planet's geological past while guiding us toward a more sustainable future.

地质学的研究包含多个子领域，其中之一是对矿物沉积的理解。在这些沉积中，术语metallogenic指的是导致金属矿石沉积形成的过程和条件。这个概念对于地质学家和采矿工程师至关重要，因为它帮助他们识别出具有高开采潜力的区域。metallogenic过程受到多种因素的影响，包括构造活动、岩浆成分和热液流体的存在。 了解一个地区的metallogenic特征可以显著影响与采矿相关的经济决策。例如，火山活动历史悠久的地区通常表现出丰富的metallogenic特征，这是由于热流体的循环可以从周围岩石中浸出金属并在某些区域浓缩。这种现象在安第斯山脉等地方尤为明显，那里地质历史创造了大量铜、金和银的沉积。 此外，矿石沉积的metallogenic分类有助于预测可能的新发现。通过研究现有沉积及其metallogenic特征，地质学家可以开发模型，建议其他地方存在类似的条件。这种预测能力对于可持续资源管理至关重要，确保我们能够满足工业需求而不过度耗竭资源。 除了经济影响，理解metallogenic过程在环境考虑中也扮演着重要角色。采矿活动可能导致栖息地破坏、水污染和其他生态影响。通过识别metallogenic区域，公司可以通过针对特定区域进行提取来最小化其环境足迹，而不是无差别地采矿大区域。 此外，探索metallogenic省份有助于我们对地球历史的了解。每个矿床都讲述了数百万年来地质过程的故事。例如，澳大利亚皮尔巴拉地区的大型铁矿石沉积与古代海洋条件和生物过程有关。理解这些metallogenic历史不仅丰富了我们的科学知识，还为未来的勘探提供了信息。 总之，术语metallogenic概括了地质学与经济资源管理之间错综复杂的关系。它突出了理解金属矿石如何形成以及在哪里可以找到的重要性。随着我们继续探索和开发这些自然资源，对metallogenic过程的全面掌握将是可持续实践和负责任地管理地球资源的关键。该领域的持续研究承诺揭示更多关于我们星球地质历史的信息，同时引导我们走向更加可持续的未来。