metallogenetic

简明释义

英[mətæləʊdʒɪˈnetɪk]美[məˌtɔːlədʒəˈnetɪk]

adj. 成矿的；产金属的

英英释义

单词用法

同义词

反义词

例句

1.The metallogenetic environment is a closed bathyal-abysmal basin and the metallogenetic setting is a rifting with characteristics of "ocean basin evolution".

成矿环境为半深水一深水局限盆地，成矿背景是以“洋盆化”为特征的裂谷作用。

2.The conclusion is that there are two important metallogenetic series and patterns at LSS metallogenetic zone.

总结出LSS成矿带具有两个重要的成矿系列、两类成矿模式。

3.Metallogenetic model is a base for the comprehensive ore-searching information model.

矿床地质模型是综合信息找矿模型的基础。

4.The east of HunChun in Jilin province is one of the most important gold metallogenetic and producing district.

吉林省珲春东部地区是一个重要的金矿成矿区和生产区。

5.These changes resulted in the differences of metallogenetic characteristics between east and west area of Gejiu.

这一变化导致个旧东、西区成矿特点的差异；

6.The metallogenetic process of the uranium and tungsten can be divided into six stages.

钨与铀的成矿过程可划分为六个阶段。

7.The metallogenetic 成矿的 characteristics of this area suggest a high potential for copper deposits.

该地区的metallogenetic 成矿的特征表明其铜矿床的潜力很高。

8.The research focused on the metallogenetic 成矿的 history of the mountain range, revealing valuable insights.

研究集中在该山脉的metallogenetic 成矿的历史上，揭示了宝贵的见解。

9.Understanding metallogenetic 成矿的 systems is crucial for successful mineral exploration.

理解metallogenetic 成矿的系统对成功的矿产勘探至关重要。

10.The geologists studied the metallogenetic 成矿的 processes that led to the formation of rich mineral deposits in the region.

地质学家研究了导致该地区丰富矿床形成的metallogenetic 成矿的过程。

11.New metallogenetic 成矿的 models have been developed to predict where precious metals might be found.

新的metallogenetic 成矿的模型已经被开发出来，以预测贵金属可能出现的位置。

作文

The field of geology encompasses various branches, one of which is the study of mineral deposits and their formation processes. A significant term in this domain is metallogenetic, which refers to the origins and evolution of metal deposits in the Earth's crust. Understanding metallogenetic processes is crucial for geologists and mining engineers, as it helps them locate and extract valuable resources more efficiently.To grasp the concept of metallogenetic, one must first consider the geological conditions that lead to the concentration of metals. These conditions include the availability of source materials, the right temperature and pressure, and the presence of fluids that can transport and deposit minerals. For instance, hydrothermal systems are often responsible for forming rich ore deposits. In these systems, hot, mineral-laden water circulates through rock formations, depositing metals as it cools or reacts with the surrounding environment.Another important aspect of metallogenetic studies is the classification of mineral deposits. Geologists categorize these deposits based on their genesis, which includes igneous, sedimentary, metamorphic, and hydrothermal processes. Each category provides insights into the geological history of an area and helps predict where new deposits might be found. For example, understanding the metallogenetic characteristics of a region can guide exploration efforts, leading to the discovery of new mines.Moreover, the concept of metallogenetic extends beyond mere academic interest; it has significant economic implications. The global demand for metals such as gold, copper, and lithium continues to rise, driven by technological advancements and the transition to renewable energy sources. As a result, mining companies invest heavily in research to understand the metallogenetic factors that influence the location and quality of mineral deposits. This investment not only enhances their operational efficiency but also contributes to sustainable mining practices by minimizing environmental impacts.Furthermore, the study of metallogenetic processes can also aid in environmental conservation. By understanding how metal deposits form and are distributed, geologists can develop better strategies for managing resources and mitigating the effects of mining activities. For instance, they can identify areas that are more susceptible to contamination or erosion, allowing for more targeted conservation efforts.In conclusion, the term metallogenetic plays a vital role in the field of geology, particularly in the study of mineral deposits. Its significance lies in the ability to provide insights into the formation, distribution, and economic potential of metal resources. As the world continues to rely on these resources for technological progress and sustainability, the importance of understanding metallogenetic processes will only grow. By investing in research and applying these findings, we can ensure that we meet our resource needs while also protecting the environment for future generations.

地质学领域包含多个分支，其中一个是矿床及其形成过程的研究。在这个领域中，一个重要的术语是metallogenetic，它指的是金属矿床在地壳中的起源和演变。理解metallogenetic过程对地质学家和采矿工程师至关重要，因为它帮助他们更有效地定位和提取有价值的资源。要掌握metallogenetic的概念，首先必须考虑导致金属浓集的地质条件。这些条件包括来源材料的可用性、适当的温度和压力，以及可以运输和沉积矿物的流体的存在。例如，热液系统通常负责形成丰富的矿石沉积。在这些系统中，热的、含矿物的水在岩石层中循环，当水冷却或与周围环境反应时，沉积出金属。metallogenetic研究的另一个重要方面是矿床的分类。地质学家根据其成因将这些矿床分类，包括火成、沉积、变质和热液过程。每个类别都提供了有关某个地区地质历史的见解，并帮助预测可能发现新矿床的位置。例如，理解一个地区的metallogenetic特征可以指导勘探工作，从而导致新矿山的发现。此外，metallogenetic的概念超越了单纯的学术兴趣，它具有重要的经济意义。全球对黄金、铜和锂等金属的需求不断上升，这一趋势受到技术进步和向可再生能源转型的推动。因此，采矿公司在研究上投入巨资，以了解影响矿床位置和质量的metallogenetic因素。这项投资不仅提高了他们的运营效率，还通过最小化环境影响来促进可持续采矿实践。此外，对metallogenetic过程的研究还可以帮助环境保护。通过了解金属矿床如何形成和分布，地质学家可以制定更好的资源管理策略，并减轻采矿活动的影响。例如，他们可以识别出更容易受到污染或侵蚀的区域，从而允许更有针对性的保护工作。总之，术语metallogenetic在地质学领域中扮演着至关重要的角色，特别是在矿床研究中。它的重要性在于能够提供有关金属资源的形成、分布和经济潜力的见解。随着世界继续依赖这些资源推动技术进步和可持续发展，理解metallogenetic过程的重要性只会增加。通过投资研究并应用这些发现，我们可以确保满足资源需求，同时保护环境，为未来几代人留出空间。