diamide
简明释义
n. [有化] 二酰胺,肼
英英释义
单词用法
有机二胺 | |
芳香族二胺 | |
脂肪族二胺 | |
二胺的合成 | |
二胺的性质 | |
二胺的应用 |
同义词
| 二胺 | 二胺常用于聚合物的合成。 | ||
| 二胺类 | 二胺可以作为有机化学中的构建块。 |
反义词
| 胺 | Amine compounds are widely used in the production of pharmaceuticals. | 胺类化合物广泛用于药品的生产。 | |
| 单体 | 单体可以聚合形成更大的分子。 |
例句
1.This paper deals with the preparation and application of the cationic diamide softening agent, which is synthesized by using cattle oil, Diethylenetriamine (DETA) and dimethyl sulfate.
以牛油、二乙烯三胺和硫酸二甲酯为主要原料合成了一种新型阳离子双酰胺类纸张柔软剂。
2.Abstract: Lipid peroxidation was initiated and facilitated in cultured human umbilical vein endothelial cells by treating the cells with diamide.
摘要:用联胺作用于培养人内皮细胞,激发并促进了脂质过氧化。
3.This paper deals with the preparation and application of the cationic diamide softening agent, which is synthesized by using cattle oil, Diethylenetriamine (DETA) and dimethyl sulfate.
以牛油、二乙烯三胺和硫酸二甲酯为主要原料合成了一种新型阳离子双酰胺类纸张柔软剂。
4.Researchers are studying the properties of diamide compounds for their potential use in drug development.
研究人员正在研究二胺化合物的性质,以便在药物开发中潜在应用。
5.The chemist explained how diamide can be used to enhance material properties.
化学家解释了如何利用二胺来增强材料性能。
6.In the laboratory, we used diamide as a building block for synthesizing more complex molecules.
在实验室中,我们使用二胺作为合成更复杂分子的基础单元。
7.The reaction yielded a stable diamide that showed promise in various applications.
该反应产生了一种稳定的二胺,在各种应用中展现了潜力。
8.The synthesis of the new polymer involved a reaction with a specific type of diamide.
新聚合物的合成涉及与特定类型的二胺反应。
作文
The world of chemistry is vast and intricate, filled with various compounds that play crucial roles in our daily lives. One such compound is diamide, which is a type of organic compound containing two amine groups. The presence of these amine groups gives diamide unique properties that make it valuable in various applications, especially in the fields of pharmaceuticals and materials science. Understanding the structure and function of diamide can provide insights into its significance in chemical reactions and synthesis processes.In essence, diamide can be seen as an evolution of simpler amines. While amines are compounds derived from ammonia, diamide takes this a step further by incorporating two amine functionalities into its structure. This duality allows diamide to participate in complex chemical reactions, often serving as a building block for larger, more complex molecules. For instance, in drug design, the incorporation of diamide structures can enhance the efficacy and selectivity of pharmaceutical agents, leading to better therapeutic outcomes.One of the most fascinating aspects of diamide is its ability to form hydrogen bonds. The presence of two amine groups enables diamide to engage in multiple hydrogen bonding interactions, which can significantly influence its physical and chemical properties. This characteristic is particularly important in biological systems, where hydrogen bonding plays a critical role in stabilizing the structures of proteins and nucleic acids. By mimicking these interactions, diamide-based compounds can potentially lead to novel drug candidates that target specific biological pathways.In addition to its role in pharmaceuticals, diamide is also gaining attention in the field of materials science. Researchers are exploring the use of diamide derivatives in the development of new polymeric materials that exhibit enhanced mechanical properties and thermal stability. These materials can find applications in various industries, including automotive, aerospace, and electronics. The versatility of diamide makes it an attractive candidate for developing innovative solutions to meet the demands of modern technology.Despite its potential, working with diamide and its derivatives requires careful consideration of safety and environmental factors. As with many chemical compounds, there may be risks associated with their synthesis and use. Therefore, researchers must adhere to strict safety protocols and conduct thorough risk assessments when handling diamide. Moreover, understanding the environmental impact of diamide production and disposal is essential to ensure sustainable practices in the chemical industry.In conclusion, diamide is a fascinating compound that bridges the gap between simple amines and more complex organic molecules. Its unique structural features and versatile properties make it a valuable asset in both pharmaceuticals and materials science. As research continues to uncover the potential applications of diamide, we can anticipate exciting developments that could revolutionize various fields. By embracing the study of diamide and its derivatives, we open the door to new discoveries that could significantly enhance our quality of life and propel scientific advancement forward.
化学的世界是广阔而复杂的,充满了在我们日常生活中发挥重要作用的各种化合物。其中一种化合物是二胺,它是一种含有两个胺基团的有机化合物。这些胺基团的存在赋予了二胺独特的性质,使其在制药和材料科学等多个应用中具有价值。理解二胺的结构和功能可以为我们提供对其在化学反应和合成过程中的重要性的洞察。从本质上讲,二胺可以被视为更简单的胺的演变。虽然胺是从氨衍生出的化合物,但二胺通过将两个胺功能团纳入其结构,进一步发展了这一概念。这种双重性使得二胺能够参与复杂的化学反应,通常作为更大、更复杂分子的构建块。例如,在药物设计中,纳入二胺结构可以增强药物的效力和选择性,从而带来更好的治疗效果。二胺最令人着迷的方面之一是它形成氢键的能力。两个胺基团的存在使得二胺能够进行多重氢键相互作用,这可以显著影响其物理和化学性质。这一特性在生物系统中尤为重要,因为氢键在稳定蛋白质和核酸的结构中发挥着关键作用。通过模仿这些相互作用,基于二胺的化合物可能导致针对特定生物通路的新药候选者。除了在制药中的角色,二胺在材料科学领域也越来越受到关注。研究人员正在探索使用二胺衍生物开发新的聚合材料,这些材料具有增强的机械性能和热稳定性。这些材料可以在汽车、航空航天和电子等多个行业中找到应用。二胺的多功能性使其成为开发满足现代技术需求的创新解决方案的有吸引力的候选者。尽管具有潜力,但处理二胺及其衍生物需要仔细考虑安全和环境因素。与许多化学化合物一样,其合成和使用可能存在风险。因此,研究人员必须遵循严格的安全协议,并在处理二胺时进行全面的风险评估。此外,了解二胺生产和处置的环境影响对于确保化学工业的可持续实践至关重要。总之,二胺是一种迷人的化合物,它架起了简单胺和更复杂有机分子之间的桥梁。其独特的结构特征和多样的性质使其在制药和材料科学中成为宝贵的资产。随着研究继续揭示二胺的潜在应用,我们可以期待激动人心的发展,这可能会革新各个领域。通过拥抱对二胺及其衍生物的研究,我们为新的发现打开了大门,这些发现可能显著提高我们的生活质量并推动科学进步。
