topochemistry

简明释义

英[/ˌtɒpəˈkɛmɪstri/]美[/ˌtɒpəˈkɛmɪstri/]

n. [化学] 局部化学

英英释义

单词用法

同义词

反义词

例句

1.The topochemistry of alkaline delignification of grasses and its effects on the pulping technique were also discussed.

草类纤维原料碱法脱木素的区域化学特性及其对制浆工艺的影响等。

2.The topochemistry of alkaline delignification of grasses and its effects on the pulping technique were also discussed.

草类纤维原料碱法脱木素的区域化学特性及其对制浆工艺的影响等。

3.The study of solid-state reactions is often referred to as topochemistry, which focuses on the spatial arrangement of atoms during chemical reactions.

固态反应的研究通常被称为拓扑化学，它关注化学反应过程中原子的空间排列。

4.In materials science, understanding topochemistry can lead to the development of new materials with desired properties.

在材料科学中，理解拓扑化学可以促进新材料的开发，以获得所需的特性。

5.Researchers are exploring topochemistry to improve the efficiency of catalysts in chemical reactions.

研究人员正在探索拓扑化学以提高化学反应中催化剂的效率。

6.The concept of topochemistry is crucial for predicting how molecular structures will change during a reaction.

在预测分子结构在反应过程中如何变化时，拓扑化学的概念至关重要。

7.Understanding the principles of topochemistry can help chemists design better drugs by optimizing molecular interactions.

理解拓扑化学的原理可以帮助化学家通过优化分子相互作用来设计更好的药物。

作文

Topochemistry is a fascinating field of study that intersects the disciplines of chemistry and materials science. It focuses on the relationship between the structural arrangement of atoms and molecules in solid materials and their chemical properties and reactions. Understanding topochemistry (拓扑化学) is essential for developing new materials with specific characteristics, which can lead to advancements in various industries, including electronics, pharmaceuticals, and energy. One of the most intriguing aspects of topochemistry (拓扑化学) is how it allows scientists to predict the behavior of materials based on their atomic structure. For example, the arrangement of atoms in a crystal lattice can significantly influence its electrical conductivity, thermal stability, and reactivity. By studying these relationships, researchers can design materials that are not only more efficient but also more sustainable. In recent years, the application of topochemistry (拓扑化学) has gained momentum in the development of novel catalysts. Catalysts play a crucial role in speeding up chemical reactions without being consumed in the process. By understanding the topochemical properties of certain materials, chemists can create more effective catalysts that lower energy barriers for reactions, leading to more efficient industrial processes. This is particularly important in the context of green chemistry, where the goal is to reduce waste and energy consumption in chemical manufacturing. Furthermore, topochemistry (拓扑化学) has significant implications in the field of drug design. The interaction between drugs and their target molecules often depends on the spatial arrangement of atoms. By applying principles of topochemistry (拓扑化学), researchers can design more effective pharmaceutical compounds that bind more efficiently to their targets, potentially leading to better therapeutic outcomes. This approach not only enhances the efficacy of drugs but also minimizes side effects, making treatments safer for patients. Additionally, the study of topochemistry (拓扑化学) is vital in the development of advanced materials for energy storage and conversion. For instance, batteries and fuel cells rely heavily on the electrochemical properties of materials. By manipulating the topochemical characteristics of these materials, scientists can improve their performance, resulting in longer-lasting batteries and more efficient fuel cells. This research is crucial for the transition to renewable energy sources, as it addresses the need for efficient energy storage solutions. In conclusion, topochemistry (拓扑化学) is an essential area of research that bridges multiple scientific disciplines. Its applications range from materials science to pharmaceuticals and energy solutions. As we continue to explore the intricate relationships between atomic structures and chemical properties, the potential for innovation in these fields is immense. By investing in topochemistry (拓扑化学) research, we can pave the way for a more sustainable and technologically advanced future.

拓扑化学是一个迷人的研究领域，它交叉了化学和材料科学的学科。它专注于固体材料中原子和分子的结构排列与其化学性质和反应之间的关系。理解拓扑化学对于开发具有特定特征的新材料至关重要，这可以推动包括电子、制药和能源在内的各个行业的进步。 拓扑化学最引人入胜的方面之一是它如何使科学家能够根据材料的原子结构预测其行为。例如，晶体格中原子的排列会显著影响其电导率、热稳定性和反应性。通过研究这些关系，研究人员可以设计出不仅更高效而且更可持续的材料。 近年来，拓扑化学在新催化剂开发中的应用获得了动力。催化剂在加速化学反应中发挥着至关重要的作用，而不会在过程中被消耗。通过理解某些材料的拓扑化学特性，化学家可以创造出更有效的催化剂，从而降低反应的能量障碍，导致更高效的工业过程。这在绿色化学的背景下尤为重要，其目标是减少化学制造中的废物和能量消耗。 此外，拓扑化学在药物设计领域具有重要意义。药物与其靶分子之间的相互作用通常依赖于原子的空间排列。通过应用拓扑化学的原理，研究人员可以设计出更有效的药物化合物，使其更有效地与靶标结合，从而潜在地导致更好的治疗结果。这种方法不仅增强了药物的疗效，还最小化了副作用，使治疗对患者更安全。 此外，拓扑化学的研究对于开发先进的能源存储和转换材料至关重要。例如，电池和燃料电池在很大程度上依赖于材料的电化学特性。通过操纵这些材料的拓扑化学特性，科学家可以提高其性能，从而产生更持久的电池和更高效的燃料电池。这项研究对于向可再生能源来源的过渡至关重要，因为它解决了对高效能源存储解决方案的需求。 总之，拓扑化学是一个重要的研究领域，连接了多个科学学科。它的应用范围从材料科学到制药和能源解决方案。随着我们继续探索原子结构与化学性质之间的复杂关系，这些领域的创新潜力巨大。通过投资于拓扑化学研究，我们可以为一个更可持续和技术先进的未来铺平道路。