bond sequence

简明释义

键合工序

英英释义

例句

1.When analyzing proteins, researchers look at the bond sequence to determine how the amino acids are linked together.

在分析蛋白质时，研究人员查看键序列以确定氨基酸是如何连接在一起的。

2.In materials science, the bond sequence can affect the properties of a substance, such as its strength and flexibility.

在材料科学中，键序列可以影响物质的特性，如强度和柔韧性。

3.In chemistry, the study of a molecule's structure often begins with identifying its bond sequence, which refers to the arrangement of atoms connected by chemical bonds.

在化学中，分子结构的研究通常从识别其键序列开始，这指的是通过化学键连接的原子的排列。

4.To synthesize a new compound, chemists must carefully plan the bond sequence to ensure the desired reactions occur.

为了合成新化合物，化学家必须仔细规划键序列以确保所需的反应发生。

5.The bond sequence in DNA is crucial for understanding genetic information and heredity.

DNA中的键序列对于理解遗传信息和遗传至关重要。

作文

In the realm of chemistry, understanding molecular structures is fundamental to grasping how substances interact and behave. One crucial concept in this field is the idea of a bond sequence, which refers to the specific arrangement of bonds between atoms in a molecule. This sequence determines not only the stability of the molecule but also its reactivity and properties. For instance, in organic chemistry, the bond sequence can dictate whether a compound is a solid, liquid, or gas at room temperature. To illustrate the importance of bond sequence, consider the difference between two isomers: butane and isobutane. Both have the same molecular formula, C4H10, but their bond sequences are different. Butane has a straight-chain structure, while isobutane has a branched structure. Despite having the same number of carbon and hydrogen atoms, their physical properties vary significantly due to their distinct bond sequences. Butane is a gas at room temperature, whereas isobutane can exist as a liquid under the same conditions. This example highlights how a small change in bond sequence can lead to vastly different characteristics in substances.Moreover, the bond sequence plays a critical role in biochemical processes. Enzymes, which are biological catalysts, often rely on specific bond sequences to function properly. The active site of an enzyme is designed to fit a particular substrate, and this fit is determined by the bond sequence of both the enzyme and the substrate. If the bond sequence is altered, even slightly, it can result in a loss of function, leading to metabolic disorders or diseases. Thus, maintaining the integrity of bond sequences in biological systems is essential for life.In addition to chemistry and biology, the concept of bond sequence extends to materials science and engineering. The properties of materials, such as strength, flexibility, and thermal conductivity, can be influenced by the bond sequences present within their structures. For example, the bond sequence in metals allows them to conduct electricity efficiently, whereas polymers with different bond sequences may exhibit insulating properties. Understanding these relationships enables scientists and engineers to design materials with specific characteristics tailored to their applications.In conclusion, the term bond sequence encapsulates a vital aspect of molecular structure that influences the behavior and properties of substances across various scientific disciplines. From chemistry to biology and materials science, the arrangement of bonds within molecules plays a pivotal role in determining how they interact with one another and their environment. A thorough comprehension of bond sequence is essential for anyone looking to delve deeper into the sciences, as it provides a foundation for understanding the complexities of molecular interactions and material properties. As research continues to advance, the significance of bond sequence will undoubtedly remain a key focus in the quest for new discoveries and innovations.

在化学领域，理解分子结构对掌握物质如何相互作用和行为至关重要。一个关键概念是键序列，它指的是分子中原子之间的特定排列。这一序列不仅决定了分子的稳定性，还决定了其反应性和性质。例如，在有机化学中，键序列可以决定一个化合物在室温下是固体、液体还是气体。为了说明键序列的重要性，我们可以考虑两种异构体：丁烷和异丁烷。它们都有相同的分子式C4H10，但它们的键序列不同。丁烷具有直链结构，而异丁烷则具有支链结构。尽管它们的碳和氢原子数量相同，但由于其不同的键序列，它们的物理性质差异显著。丁烷在室温下是气体，而异丁烷在相同条件下可以作为液体存在。这个例子突显了键序列的小变化如何导致物质特征的巨大差异。此外，键序列在生化过程中也起着关键作用。酶，作为生物催化剂，通常依赖于特定的键序列才能正常发挥功能。酶的活性位点设计为适合特定底物，而这种适配性由酶和底物的键序列决定。如果键序列发生了微小的变化，可能会导致功能丧失，从而引发代谢紊乱或疾病。因此，维持生物系统中键序列的完整性对于生命至关重要。除了化学和生物学，键序列的概念还扩展到材料科学和工程学。材料的性质，如强度、柔韧性和热导率，可能会受到其结构内的键序列的影响。例如，金属中的键序列使其能够有效导电，而具有不同键序列的聚合物可能表现出绝缘特性。理解这些关系使科学家和工程师能够设计具有特定特性的材料，以满足其应用需求。总之，键序列这一术语概括了分子结构的一个重要方面，它影响着各个科学学科中物质的行为和性质。从化学到生物学再到材料科学，分子内的键的排列在决定它们如何相互作用以及与环境的关系中发挥着关键作用。全面理解键序列对于任何希望深入研究科学的人来说都是必不可少的，因为它为理解分子相互作用和材料特性的复杂性提供了基础。随着研究的不断推进，键序列的重要性无疑将继续成为新发现和创新追求的重点。