keesom relationship

简明释义

基朔关系

英英释义

例句

1.Chemists often study the keesom relationship 分子间的相互作用 to predict how different substances will interact.

化学家们常常研究keesom relationship 分子间的相互作用以预测不同物质之间的相互作用。

2.Researchers are exploring the keesom relationship 分子间的相互作用 to develop new materials for energy storage.

研究人员正在探索keesom relationship 分子间的相互作用以开发用于能量储存的新材料。

3.Understanding the keesom relationship 分子间的相互作用 helps in designing better drugs that can target specific cells.

理解keesom relationship 分子间的相互作用有助于设计更好的药物，以针对特定细胞。

4.The keesom relationship 分子间的相互作用 is crucial in determining the physical properties of materials.

在决定材料的物理性质时，keesom relationship 分子间的相互作用至关重要。

5.In a team setting, understanding the keesom relationship 分子间的相互作用 can improve collaboration and synergy among members.

在团队环境中，理解keesom relationship 分子间的相互作用可以改善成员之间的协作与协同。

作文

In the realm of chemistry, various types of interactions dictate how molecules behave and interact with one another. One such interaction is known as a keesom relationship, which refers to the attractive forces between permanent dipoles in polar molecules. Understanding this type of relationship is crucial for grasping the complexities of molecular interactions and their implications in both biological systems and material science.The keesom relationship arises when two molecules, each possessing a permanent dipole moment, come into close proximity. The positive end of one dipole is attracted to the negative end of another, leading to a stabilization of the system. This phenomenon can be observed in various substances, particularly in polar solvents like water, where molecules exhibit strong keesom relationships due to their inherent polarity.One of the most significant implications of keesom relationships can be seen in the properties of liquids. For instance, the high boiling point of water compared to nonpolar solvents can be attributed to the strong keesom relationships present among water molecules. These interactions require more energy to break, resulting in a higher boiling point. Similarly, the solubility of ionic compounds in polar solvents is also influenced by keesom relationships, as the polar solvent molecules stabilize the ions through these dipole-dipole interactions.In biological systems, the keesom relationship plays a vital role in the structure and function of proteins and nucleic acids. The stability of protein structures is heavily reliant on these dipole interactions, which help maintain the three-dimensional conformation necessary for biological activity. Furthermore, the binding of substrates to enzymes often involves keesom relationships, facilitating the catalytic processes that are essential for life.Moreover, understanding keesom relationships is not limited to biological contexts; it also extends to material science. For example, in the development of polymers, the presence of polar groups can enhance the mechanical properties of the material due to the formation of keesom relationships between polymer chains. This knowledge allows scientists and engineers to design materials with specific characteristics tailored for particular applications.In conclusion, the keesom relationship is a fundamental concept that underscores many aspects of chemistry, biology, and material science. By recognizing the significance of these dipole-dipole interactions, we can better understand the behavior of molecules in various environments. Whether it is the unique properties of water, the intricate structures of proteins, or the innovative designs of new materials, keesom relationships are at the heart of numerous scientific advancements. As research continues to evolve, further exploration of these interactions will undoubtedly lead to new discoveries and applications across multiple disciplines.

在化学领域，各种相互作用决定了分子的行为和相互作用。其中一种相互作用被称为keesom关系，它指的是极性分子中永久偶极之间的吸引力。理解这种关系对于掌握分子相互作用的复杂性及其在生物系统和材料科学中的影响至关重要。keesom关系发生在两个具有永久偶极矩的分子接近时。一个偶极的正端吸引另一个偶极的负端，从而导致系统的稳定。这种现象可以在各种物质中观察到，特别是在水等极性溶剂中，分子由于其固有的极性而表现出强烈的keesom关系。keesom关系的一个重要影响可以在液体的性质中看到。例如，水的高沸点与非极性溶剂相比，可以归因于水分子之间存在的强keesom关系。这些相互作用需要更多的能量来打破，从而导致更高的沸点。同样，离子化合物在极性溶剂中的溶解度也受到keesom关系的影响，因为极性溶剂分子通过这些偶极-偶极相互作用来稳定离子。在生物系统中，keesom关系在蛋白质和核酸的结构和功能中发挥着至关重要的作用。蛋白质结构的稳定性在很大程度上依赖于这些偶极相互作用，这有助于维持生物活性所需的三维构象。此外，底物与酶的结合往往涉及keesom关系，促进了生命必需的催化过程。此外，理解keesom关系并不仅限于生物背景；它还扩展到材料科学。例如，在聚合物的开发中，极性基团的存在可以通过聚合物链之间形成的keesom关系增强材料的机械性能。这一知识使科学家和工程师能够设计具有特定特性的材料，以满足特定应用的需求。总之，keesom关系是一个基本概念，强调了化学、生物学和材料科学的许多方面。通过认识到这些偶极-偶极相互作用的重要性，我们可以更好地理解分子在各种环境中的行为。无论是水的独特性质、蛋白质的复杂结构，还是新材料的创新设计，keesom关系都是众多科学进展的核心。随着研究的不断发展，对这些相互作用的进一步探索无疑将导致多个学科的新发现和应用。