compound chain

简明释义

并车链条;

英英释义

例句

1.In chemistry, a molecule can be described as a compound chain 复合链 of atoms bonded together.

在化学中，一个分子可以被描述为一条复合链 compound chain，由相互结合的原子组成。

2.The compound chain 复合链 of events led to the final decision in the project.

事件的复合链 compound chain 导致了项目的最终决定。

3.The design of the software was based on a compound chain 复合链 of user requirements.

软件的设计基于用户需求的复合链 compound chain。

4.In genetics, a compound chain 复合链 of DNA sequences can determine an organism's traits.

在遗传学中，DNA序列的复合链 compound chain 可以决定生物体的特征。

5.When analyzing data, we often look for a compound chain 复合链 of correlations between variables.

在分析数据时，我们通常会寻找变量之间的复合链 compound chain 相关性。

作文

In the world of chemistry and materials science, understanding complex structures is essential for innovation and development. One such structure that has gained attention is the compound chain. A compound chain refers to a series of interconnected molecules or atoms that create a larger, more complex entity. These chains can be found in various substances, including polymers, proteins, and even in the formation of certain minerals. The properties of these compound chains significantly influence the characteristics of the materials they compose.To illustrate the importance of compound chains, let’s consider the example of synthetic polymers. Polymers are made up of long sequences of repeating units, known as monomers. When these monomers link together to form a compound chain, they create materials that possess unique properties such as flexibility, strength, and durability. For instance, polyethylene, one of the most common plastics, consists of a long compound chain of ethylene monomers. The physical properties of polyethylene, such as its resistance to moisture and chemicals, are directly attributed to the nature of its compound chain structure.Moreover, in biological systems, compound chains play a critical role in the functioning of living organisms. Proteins, which are essential for life, are made up of amino acids linked together in a specific sequence to form compound chains. The particular arrangement and length of these chains determine the protein's shape and function. For example, enzymes, which catalyze biochemical reactions, rely on their compound chain structure to maintain their active sites, allowing them to interact with substrates effectively.The study of compound chains also extends to the field of nanotechnology. Researchers are exploring how to manipulate compound chains at the molecular level to create new materials with enhanced properties. By controlling the length and composition of these chains, scientists can design materials with specific characteristics, such as increased conductivity or improved strength. This ability to engineer compound chains opens up exciting possibilities in fields ranging from electronics to medicine.However, understanding compound chains is not without its challenges. The interactions between different molecules in a compound chain can lead to unpredictable behaviors, making it difficult to predict how a material will perform in real-world applications. Therefore, extensive research is necessary to fully grasp the implications of compound chains in various contexts.In conclusion, the concept of compound chains is fundamental to many scientific disciplines, including chemistry, biology, and materials science. By studying these interconnected structures, we can unlock new technologies and improve existing materials. As our understanding of compound chains deepens, we can expect to see significant advancements in various industries, ultimately enhancing our quality of life. The exploration of compound chains is not just an academic pursuit; it is a pathway to innovation and progress in the modern world.

在化学和材料科学的世界中，理解复杂结构对于创新和发展至关重要。其中一个引起关注的结构是复合链。复合链指的是一系列相互连接的分子或原子，形成一个更大、更复杂的实体。这些链可以在各种物质中找到，包括聚合物、蛋白质，甚至某些矿物的形成。这些复合链的性质显著影响它们所组成材料的特性。为了说明复合链的重要性，让我们考虑合成聚合物的例子。聚合物由长序列的重复单元（称为单体）组成。当这些单体连接在一起形成复合链时，它们创造出具有独特性质的材料，例如灵活性、强度和耐久性。例如，聚乙烯是最常见的塑料之一，由乙烯单体组成的长复合链构成。聚乙烯的物理性质，如对湿气和化学品的抵抗力，直接归因于其复合链结构的性质。此外，在生物系统中，复合链在生命体的功能中扮演着关键角色。蛋白质是生命所必需的，由氨基酸以特定顺序连接在一起形成复合链。这些链的特定排列和长度决定了蛋白质的形状和功能。例如，催化生化反应的酶依赖于其复合链结构来维持其活性位点，从而有效地与底物相互作用。复合链的研究还扩展到纳米技术领域。研究人员正在探索如何在分子水平上操纵复合链，以创造具有增强属性的新材料。通过控制这些链的长度和组成，科学家可以设计具有特定特性的材料，例如提高导电性或改善强度。工程化复合链的能力为电子学到医学等多个领域开辟了激动人心的可能性。然而，理解复合链并非没有挑战。在复合链中，不同分子之间的相互作用可能导致不可预测的行为，使得难以预测材料在实际应用中的表现。因此，需要进行广泛的研究，以充分掌握复合链在各种上下文中的影响。总之，复合链的概念是许多科学学科的基础，包括化学、生物学和材料科学。通过研究这些相互连接的结构，我们可以解锁新技术并改善现有材料。随着我们对复合链的理解加深，我们可以期待在各个行业看到重大进展，最终提升我们的生活质量。探索复合链不仅仅是一项学术追求；它是现代世界创新和进步的途径。