hydrogenous
简明释义
英[haɪˈdrɒdʒɪnəs]美[haɪˈdrɑːdʒənəs]
adj. 氢的;含氢的
英英释义
与氢有关或含有氢的。 |
单词用法
氢源物质 | |
氢化合物 | |
氢源材料 | |
氢源溶液 |
同义词
| 水的 | 水土通常出现在湿地中。 | ||
| 水状的 | 水溶液常用于化学反应中。 |
反义词
| 非氢的 | The non-hydrogenous compounds are often used in industrial applications. | 非氢化合物常用于工业应用。 | |
| 脱氢的 | Dehydrogenated substances can be more stable than their hydrogenous counterparts. | 脱氢物质比其氢化物更稳定。 |
例句
1.In this study trimethyl amine was reclaimed from amination wastewater by using 001 hydrogenous strong-acid ion exchange resin. The recovery ratio is more than 90%.
本文采用001氢型强酸性阳离子交换树脂从胺化废水中回收三甲胺,回收率大于90%。
2.In this study trimethyl amine was reclaimed from amination wastewater by using 001 hydrogenous strong-acid ion exchange resin. The recovery ratio is more than 90%.
本文采用001氢型强酸性阳离子交换树脂从胺化废水中回收三甲胺,回收率大于90%。
3.The catalyst is applicable to preparation of hydroflurocarbon and hydrogenous fluorochlorohydrocarbon with gas-phase fluorinated halohydrocarbon.
该催化剂适用于气相氟化卤代烃制备氢氟烃和氢氟氯烃。
4.In oceanography, hydrogenous 氢的 sediments are formed from chemical processes in seawater.
在海洋学中,hydrogenous 氢的沉积物是由海水中的化学过程形成的。
5.The research team discovered that the mineral was primarily composed of hydrogenous 氢的 materials.
研究团队发现这种矿物主要由hydrogenous 氢的材料组成。
6.Scientists are studying hydrogenous 氢的 minerals for their potential use in renewable energy.
科学家正在研究hydrogenous 氢的矿物,以探索其在可再生能源中的潜在应用。
7.The formation of hydrogenous 氢的 rocks is a key process in the geological cycle.
形成hydrogenous 氢的岩石是地质循环中的一个关键过程。
8.The presence of hydrogenous 氢的 compounds can affect the pH levels of aquatic environments.
存在的hydrogenous 氢的化合物会影响水生环境的pH水平。
作文
In the study of chemistry and material science, the term hydrogenous is often used to describe substances that are rich in hydrogen or contain hydrogen as a significant component. Understanding the properties and applications of hydrogenous materials can provide valuable insights into various scientific fields, including energy production, environmental science, and even biology. For instance, hydrogen plays a crucial role in the formation of organic compounds, which are the building blocks of life. This makes hydrogenous compounds essential for understanding biochemical processes. One of the most notable applications of hydrogenous materials is in the field of renewable energy. Hydrogen fuel cells are gaining popularity as a clean energy source because they produce electricity by combining hydrogen with oxygen, emitting only water as a byproduct. This process highlights the importance of hydrogenous substances in creating sustainable energy solutions that can help combat climate change. By harnessing the power of hydrogen, researchers and engineers are developing innovative technologies that could lead to a greener future.Moreover, the presence of hydrogenous materials in our environment cannot be overlooked. Many natural resources, such as fossil fuels and biomass, are composed of hydrogenous compounds. These resources have been utilized for centuries to meet our energy needs, but their extraction and use have significant environmental impacts. As we strive to transition to more sustainable practices, understanding the role of hydrogenous materials in both traditional and alternative energy sources is crucial.In addition to energy applications, hydrogenous compounds also play a vital role in various industrial processes. For example, in the production of ammonia, which is a key ingredient in fertilizers, hydrogen is combined with nitrogen from the air. This process, known as the Haber-Bosch process, relies heavily on hydrogenous materials to produce ammonia efficiently. The availability and cost of hydrogen can significantly impact agricultural productivity, making it essential to explore new methods of hydrogen production that are both economical and environmentally friendly.Furthermore, the study of hydrogenous materials extends to the realm of space exploration. Scientists are investigating the potential of using hydrogen as a fuel source for rockets and other spacecraft. The high energy content of hydrogenous fuels makes them an attractive option for long-duration missions beyond Earth. As humanity looks to explore Mars and beyond, understanding the properties of hydrogenous materials will be critical in developing the technologies necessary for these ambitious endeavors.In conclusion, the significance of hydrogenous materials spans across multiple disciplines, from energy production to agriculture and space exploration. As we continue to face global challenges such as climate change and resource depletion, the study and application of hydrogenous substances will become increasingly important. By investing in research and innovation related to hydrogenous materials, we can pave the way for a more sustainable and prosperous future for generations to come.
在化学和材料科学的研究中,术语hydrogenous通常用于描述富含氢或含有氢作为重要成分的物质。理解hydrogenous材料的性质和应用可以为包括能源生产、环境科学甚至生物学在内的各种科学领域提供有价值的见解。例如,氢在有机化合物的形成中起着至关重要的作用,而有机化合物是生命的基本构件。这使得hydrogenous化合物对于理解生化过程至关重要。hydrogenous材料最显著的应用之一是在可再生能源领域。氢燃料电池因其通过将氢与氧结合来产生电力,只排放水作为副产品,因此越来越受到青睐,成为清洁能源来源。这一过程突显了hydrogenous物质在创造可持续能源解决方案中的重要性,这些解决方案有助于应对气候变化。通过利用氢的力量,研究人员和工程师正在开发创新技术,这可能导致一个更环保的未来。此外,hydrogenous材料在我们环境中的存在也不容忽视。许多自然资源,如化石燃料和生物质,都是由hydrogenous化合物组成的。这些资源被利用了几个世纪来满足我们的能源需求,但它们的开采和使用对环境造成了重大影响。在我们努力过渡到更可持续的实践时,理解hydrogenous材料在传统和替代能源来源中的作用至关重要。除了能源应用,hydrogenous化合物在各种工业过程中也发挥着重要作用。例如,在氨的生产中,氢与空气中的氮结合。这个过程被称为哈伯-博施法,它在高效生产氨时严重依赖hydrogenous材料。氢的可用性和成本会显著影响农业生产力,因此探索既经济又环保的氢生产新方法至关重要。此外,hydrogenous材料的研究还扩展到太空探索的领域。科学家们正在研究使用氢作为火箭和其他航天器燃料来源的潜力。hydrogenous燃料的高能量含量使其成为长期任务的有吸引力的选择。随着人类寻求探索火星及更远的地方,理解hydrogenous材料的特性将在开发这些雄心勃勃的技术中至关重要。总之,hydrogenous材料的重要性跨越多个学科,从能源生产到农业和太空探索。随着我们继续面临气候变化和资源枯竭等全球挑战,hydrogenous物质的研究和应用将变得越来越重要。通过投资与hydrogenous材料相关的研究和创新,我们可以为未来几代人铺平更加可持续和繁荣的道路。
