mineralogical

简明释义

英[ˌmɪnərəˈlɒdʒɪkl]美[ˌmɪnərəˈlɑːdʒɪkl]

adj. 矿物学的

英英释义

单词用法

同义词

反义词

例句

1.The mineralogical, gemmological and spectral characteristics of this kind of jade is studied by using the slice observation, electron microprobe and infrared spectrum.

采用薄片观察、电子探针、红外光谱等测试手段，对其样品的矿物学、宝石学、谱学特征进行了研究。

2.A series of mineralogical parameters have been obtained.

取得了一系列的矿物学参数。

3.The mineralogical crystalline essence is essentially the root-resonance of the same creative force that formed the Cosmos.

矿物晶体的本质，基本上其根源共振与形成宇宙的创作力量是相同的。

4.The mineralogical analysis; strength and density measurement were conducted with the samples taken from the sinter cake on the pallets.

从台车烧结饼上取样，进行了物相分析、强度测定、密度测定；

5.Some mineralogical characteristics of scawtite from the Zoulou iron deposit, Suixi County, Anhui Province are reported in this paper.

本文碳硅钙石产于安徽濉溪邹楼铁矿床中。

6.The paper mainly introduces its mineralogical characteristics quality and utilization.

本文主要介绍矿床地质特征、矿石质量及可能利用方向。

7.She specialized in mineralogical research, focusing on rare earth elements.

她专注于矿物学研究，重点研究稀土元素。

8.The geologist conducted a thorough study of the rock samples to determine their mineralogical composition.

地质学家对岩石样本进行了详细研究，以确定它们的矿物学成分。

9.The mineralogical analysis revealed unexpected findings about the region's geology.

这项矿物学分析揭示了该地区地质的意外发现。

10.The museum exhibit featured a section dedicated to mineralogical specimens from around the world.

博物馆展览有一个专门展示来自世界各地的矿物学标本的部分。

11.Understanding the mineralogical properties of soil can help in agricultural planning.

了解土壤的矿物学特性可以帮助农业规划。

作文

The study of rocks and minerals is a fascinating field that encompasses various scientific disciplines. One of the key aspects of this study is the understanding of their mineralogical properties, which refers to the characteristics and composition of minerals found within rocks. This knowledge is crucial for geologists and earth scientists as it helps them decipher the history and formation of the Earth’s crust. By examining the mineralogical features of a rock sample, scientists can determine its age, origin, and the environmental conditions under which it formed.Minerals are naturally occurring substances, and each one has a unique chemical structure and physical properties. The mineralogical classification of these minerals includes categories such as silicates, carbonates, oxides, and sulfates, among others. For instance, quartz, which is a common silicate mineral, is composed of silicon dioxide and is known for its hardness and resistance to weathering. Understanding the mineralogical composition of a rock can reveal important information about the geological processes that shaped it, including volcanic activity, sedimentation, and metamorphism.In addition to their geological significance, the mineralogical properties of minerals have practical applications in various industries. For example, the construction industry relies heavily on minerals like granite and limestone, which are valued for their strength and durability. Similarly, the electronics industry utilizes quartz in the production of high-frequency oscillators due to its piezoelectric properties. Therefore, a thorough understanding of the mineralogical characteristics of these materials is essential for their effective use in manufacturing and construction.Moreover, the field of mineralogical research is continuously evolving with advancements in technology. Techniques such as X-ray diffraction and scanning electron microscopy allow scientists to analyze the mineralogical composition of samples at a microscopic level, revealing details that were previously inaccessible. These innovations not only enhance our understanding of mineral structures but also contribute to the discovery of new minerals and materials that can be utilized in various applications.Education plays a vital role in promoting awareness of mineralogical sciences. Schools and universities offer courses that explore the properties and uses of minerals, encouraging students to appreciate the natural world around them. Field trips to geological sites provide hands-on experience, allowing students to collect samples and observe the mineralogical diversity present in different environments. Such educational initiatives inspire future generations to pursue careers in geology, environmental science, and related fields.In conclusion, the term mineralogical encapsulates a critical aspect of earth sciences, encompassing the study of minerals and their properties. From geological research to industrial applications, the understanding of mineralogical characteristics is fundamental in various domains. As we continue to explore and learn about the Earth’s materials, the importance of mineralogical studies will undoubtedly grow, paving the way for new discoveries and innovations that benefit society as a whole.

岩石和矿物的研究是一个迷人的领域，涵盖了各种科学学科。其中一个关键方面是理解它们的矿物学特性，这指的是矿物在岩石中存在的特征和成分。这一知识对地质学家和地球科学家至关重要，因为它帮助他们解读地球地壳的历史和形成。通过检查岩石样本的矿物学特征，科学家可以确定其年龄、起源以及形成时的环境条件。矿物是自然发生的物质，每种矿物都有独特的化学结构和物理特性。矿物学分类包括硅酸盐、碳酸盐、氧化物和硫酸盐等类别。例如，石英是一种常见的硅酸盐矿物，由二氧化硅组成，以其硬度和抗风化性而闻名。了解岩石的矿物学成分可以揭示出塑造它的地质过程的重要信息，包括火山活动、沉积和变质作用。除了地质意义外，矿物的矿物学特性在各个行业中也具有实际应用。例如，建筑行业严重依赖于花岗岩和石灰石等矿物，这些矿物因其强度和耐久性而受到重视。同样，电子行业利用石英生产高频振荡器，因为其压电特性。因此，对这些材料的矿物学特性的透彻理解对于它们在制造和建筑中的有效使用至关重要。此外，随着技术的进步，矿物学研究领域不断发展。X射线衍射和扫描电子显微镜等技术使科学家能够在微观水平上分析样本的矿物学成分，揭示之前无法获取的细节。这些创新不仅增强了我们对矿物结构的理解，还促进了新矿物和材料的发现，这些材料可以应用于各种用途。教育在提高对矿物学科学的认识中发挥着至关重要的作用。学校和大学提供课程，探索矿物的特性和用途，鼓励学生欣赏周围的自然世界。前往地质遗址的实地考察提供了动手经验，让学生收集样本并观察不同环境中存在的矿物学多样性。这类教育倡议激励未来几代人追求地质学、环境科学及相关领域的职业。总之，术语矿物学概括了地球科学的一个关键方面，涵盖了对矿物及其特性的研究。从地质研究到工业应用，对矿物学特性的理解在各个领域都是基础。随着我们不断探索和学习地球的材料，矿物学研究的重要性无疑会增长，为新的发现和创新铺平道路，从而惠及整个社会。