butylate

简明释义

英[ˈbjʊtɪˌleɪt]美[betiːˈleɪt]

v. 把丁基引进；使……丁化

复 数 b u t y l a t e s

第 三 人 称 单 数 b u t y l a t e s

现 在 分 词 b u t y l a t i n g

过 去 式 b u t y l a t e d

过 去 分 词 b u t y l a t e d

英英释义

单词用法

同义词

反义词

例句

1.The chemist decided to butylate the compound to enhance its stability.

化学家决定对化合物进行丁基化以增强其稳定性。

2.In the laboratory, we learned how to butylate various organic molecules.

在实验室中，我们学习了如何对各种有机分子进行丁基化。

3.To improve the solubility of the substance, the researchers chose to butylate it.

为了提高物质的溶解度，研究人员选择对其进行丁基化。

4.The process of butylating can significantly alter the physical properties of a molecule.

对分子进行丁基化的过程可以显著改变其物理性质。

5.We need to butylate this polymer to make it more resistant to degradation.

我们需要对这个聚合物进行丁基化，以使其更耐降解。

作文

In the world of chemistry, the term butylate refers to the process of introducing a butyl group into a molecule. This reaction is essential in organic synthesis and is commonly used in the production of various chemicals and pharmaceuticals. Understanding how to butylate compounds can lead to the development of new materials with unique properties. For instance, when we butylate certain polymers, we can enhance their flexibility and durability, making them suitable for a wide range of applications. The process of butylate involves several steps, including the selection of the appropriate reagents and conditions that facilitate the reaction. Chemists often use butyl halides as the source of the butyl group, which can be attached to different substrates through nucleophilic substitution reactions. The ability to effectively butylate compounds is crucial for researchers in the field of medicinal chemistry, as it allows them to modify drug molecules to improve their efficacy and reduce side effects. Moreover, the significance of butylate extends beyond just chemical reactions. In environmental science, understanding how certain compounds can be butylated helps scientists assess their behavior and fate in the environment. For example, some pollutants can be butylated, affecting their solubility and toxicity. Therefore, knowledge of this process is vital for developing strategies to remediate contaminated sites. In the realm of industrial applications, butylated products are widely used in the formulation of coatings, adhesives, and sealants. These products benefit from the enhanced properties imparted by the butyl groups. For instance, coatings that have been butylated often exhibit improved adhesion and resistance to weathering, making them ideal for outdoor applications. Similarly, adhesives that incorporate butylated components tend to have superior bonding strength and flexibility. Furthermore, the study of butylated compounds is an area of ongoing research. Scientists are constantly exploring new ways to utilize the butyl group to create innovative materials. For example, recent studies have shown that butylated nanoparticles can be used in drug delivery systems, providing targeted therapy with minimal side effects. This advancement highlights the importance of understanding the butylate process and its implications in modern science. In conclusion, the term butylate plays a significant role in various scientific disciplines, from organic chemistry to environmental science and industrial applications. By mastering the concept of butylate, researchers and professionals can unlock new possibilities in material development, pollution management, and pharmaceutical advancements. As we continue to explore the potential of butylated compounds, the future holds exciting prospects for innovation and discovery in many fields.

在化学领域，术语butylate指的是将丁基引入分子的过程。这一反应在有机合成中至关重要，通常用于生产各种化学品和药物。理解如何butylate化合物可以导致开发出具有独特性质的新材料。例如，当我们butylate某些聚合物时，可以增强它们的柔韧性和耐用性，使其适用于广泛的应用。 butylate的过程包括几个步骤，包括选择适当的试剂和促进反应的条件。化学家通常使用丁基卤化物作为丁基的来源，可以通过亲核取代反应将其附加到不同的底物上。有效地butylate化合物的能力对医学化学领域的研究人员至关重要，因为这使他们能够修饰药物分子以提高其疗效并减少副作用。 此外，butylate的意义不仅限于化学反应。在环境科学中，理解某些化合物如何被butylate有助于科学家评估其在环境中的行为和命运。例如，一些污染物可以被butylate，影响其溶解度和毒性。因此，了解这一过程对于制定修复受污染地点的策略至关重要。 在工业应用领域，butylate产品广泛用于涂料、粘合剂和密封剂的配方。这些产品受益于丁基所赋予的增强特性。例如，经过butylate的涂料通常表现出更好的附着力和抗风化能力，使其非常适合户外应用。同样，包含butylate成分的粘合剂往往具有优越的粘结强度和柔韧性。 此外，butylate化合物的研究是一个持续进行的研究领域。科学家们不断探索利用丁基创造创新材料的新方法。例如，最近的研究表明，butylate纳米颗粒可用于药物递送系统，提供靶向治疗，副作用最小。这一进展突显了理解butylate过程及其在现代科学中影响的重要性。 总之，术语butylate在多个科学学科中发挥着重要作用，从有机化学到环境科学和工业应用。通过掌握butylate的概念，研究人员和专业人士可以在材料开发、污染管理和药物进步方面开启新的可能性。随着我们继续探索butylate化合物的潜力，未来在许多领域的创新和发现充满了令人兴奋的前景。