pyrogenetic
简明释义
英[/ˌpaɪrəʊdʒəˈnɛtɪk/]美[/ˌpaɪrəʊdʒəˈnɛtɪk/]
adj. 热发生的;火成的
英英释义
Relating to or caused by the generation of heat, especially in a geological context. | 与热的生成有关或由其引起,特别是在地质学的背景下。 |
单词用法
同义词
| 热生的 | 体内的热生过程可以影响新陈代谢。 | ||
| 产生热量的 | Heat-producing reactions are essential for maintaining body temperature. | 产生热量的反应对于维持体温至关重要。 |
反义词
| 冷却 | 冷却过程对食品保存至关重要。 | ||
| 制冷 | Refrigeration technology has advanced significantly in recent years. | 制冷技术近年来有了显著进步。 |
例句
1.Nanometer sized lead oxide was prepared by pyrogenetic decomposition of lead carbonate synthesized by chemical precipitation.
采用均匀沉淀法合成碳酸铅,在此基础上通过高温分解制备纳米氧化铅。
2.Objective To probe the more effective methods treating pyrogenetic reaction induced by transfusion.
目的探讨治疗输液发热反应更为有效的方法。
3.Nanometer sized lead oxide was prepared by pyrogenetic decomposition of lead carbonate synthesized by chemical precipitation.
采用均匀沉淀法合成碳酸铅,在此基础上通过高温分解制备纳米氧化铅。
4.Scientists often analyze pyrogenetic 火成的 materials to learn more about Earth's geological history.
科学家们常常分析pyrogenetic 火成的材料,以了解更多关于地球地质历史的信息。
5.In geology, understanding pyrogenetic 火成的 processes is crucial for predicting future eruptions.
在地质学中,理解pyrogenetic 火成的过程对于预测未来的喷发至关重要。
6.The study revealed that the volcanic activity was primarily pyrogenetic 火成的, contributing to the formation of new land.
研究表明,火山活动主要是pyrogenetic 火成的,促进了新土地的形成。
7.The pyrogenetic 火成的 nature of the rocks indicates a history of intense volcanic activity.
这些岩石的pyrogenetic 火成的特性表明它们经历过强烈的火山活动。
8.The researchers focused on the pyrogenetic 火成的 origins of certain minerals found in the area.
研究人员集中研究该地区发现的某些矿物的pyrogenetic 火成的起源。
作文
The study of earth sciences encompasses a wide range of topics, one of which is the concept of volcanic activity. Volcanic eruptions are fascinating phenomena that can have profound effects on the environment and human life. One important aspect of volcanology is the understanding of the processes involved in the formation of magma and its subsequent eruption. This leads us to the term pyrogenetic, which refers to processes related to the generation of heat and the formation of igneous rocks through volcanic activity. Understanding pyrogenetic processes is crucial for geologists and researchers who seek to predict volcanic eruptions and mitigate their impacts on society.Volcanic eruptions are driven by the movement of magma from the Earth's interior to the surface. This movement is influenced by various factors, including the temperature and pressure conditions within the Earth. The term pyrogenetic highlights the thermal aspects of these processes, as heat plays a vital role in the melting of rocks and the formation of magma. When rocks melt due to extreme temperatures, they become molten and can rise through cracks in the Earth's crust, leading to volcanic eruptions.In addition to its geological significance, the concept of pyrogenetic processes also has implications for understanding the impact of volcanic eruptions on climate change. For instance, large-scale eruptions can release significant amounts of ash and gases into the atmosphere, which can affect global temperatures. The heat generated during these eruptions can lead to short-term warming, while the particles released can contribute to cooling by reflecting sunlight away from the Earth’s surface. Thus, the study of pyrogenetic processes not only informs us about the mechanisms of volcanic eruptions but also connects to broader environmental issues.Moreover, the pyrogenetic nature of volcanic activity can influence the formation of new landforms. When lava cools and solidifies, it creates various types of igneous rock formations, such as basalt and pumice. These rocks play an essential role in shaping the landscape and providing habitats for diverse ecosystems. Understanding the pyrogenetic processes involved in rock formation helps scientists appreciate the dynamic nature of our planet and the intricate relationships between geological activity and biological diversity.In conclusion, the term pyrogenetic encapsulates the complex interactions between heat generation, volcanic activity, and geological formations. By studying these processes, we gain valuable insights into the Earth's behavior and its impact on our environment. As we continue to explore the mysteries of our planet, the knowledge of pyrogenetic phenomena will remain a vital part of our understanding of earth sciences, helping us to predict future volcanic activity and protect our communities from potential hazards.
地球科学的研究涵盖了广泛的主题,其中一个是火山活动的概念。火山喷发是迷人的现象,会对环境和人类生活产生深远的影响。火山学的一个重要方面是理解形成岩浆及其随后的喷发过程。这使我们想到了术语pyrogenetic,它指的是与热量生成相关的过程,以及通过火山活动形成的火成岩。理解pyrogenetic过程对于地质学家和研究人员来说至关重要,他们试图预测火山喷发并减轻其对社会的影响。火山喷发是由岩浆从地球内部移动到地表驱动的。这种运动受到多种因素的影响,包括地球内部的温度和压力条件。术语pyrogenetic突出了这些过程的热特性,因为热量在岩石熔化和岩浆形成中发挥着重要作用。当岩石由于极端温度而熔化时,它们变为液态并可以通过地壳中的裂缝上升,导致火山喷发。除了其地质意义外,pyrogenetic过程的概念还与理解火山喷发对气候变化的影响有关。例如,大规模喷发可以向大气释放大量灰烬和气体,这会影响全球温度。喷发过程中产生的热量可以导致短期升温,而释放的颗粒则可以通过反射阳光使地球表面降温。因此,研究pyrogenetic过程不仅让我们了解火山喷发的机制,还与更广泛的环境问题相联系。此外,火山活动的pyrogenetic特性可以影响新地貌的形成。当熔岩冷却并固化时,会形成各种类型的火成岩,如玄武岩和浮石。这些岩石在塑造地貌和提供多样生态系统栖息地方面发挥着重要作用。理解岩石形成中的pyrogenetic过程有助于科学家欣赏我们星球的动态性质以及地质活动与生物多样性之间的复杂关系。总之,术语pyrogenetic概括了热量生成、火山活动和地质形成之间的复杂相互作用。通过研究这些过程,我们获得了对地球行为及其对环境影响的宝贵见解。随着我们继续探索我们星球的奥秘,对pyrogenetic现象的知识将始终是我们理解地球科学的重要组成部分,帮助我们预测未来的火山活动并保护我们的社区免受潜在危害。
