compound; multiplicity; recombination

简明释义

复合

英英释义

例句

1.In programming, you can create a compound 复合 data structure that holds a multiplicity 多样性 of data types, which can be modified through recombination 重组 of its components.

在编程中，你可以创建一个包含多种数据类型的compound 复合数据结构，这可以通过其组件的recombination 重组来修改。

2.The financial model is based on a compound 复合 interest system, which accounts for the multiplicity 多样性 of investments and their potential recombination 重组 over time.

这个金融模型基于一个compound 复合利息系统，它考虑到投资的multiplicity 多样性及其随时间的潜在recombination 重组。

3.The multiplicity 多样性 of genes in an organism can lead to various traits, which can be analyzed through compound 复合 genetic studies that focus on recombination 重组 events.

一个生物体内基因的multiplicity 多样性可以导致各种特征，这可以通过关注recombination 重组事件的compound 复合遗传研究进行分析。

4.In chemistry, when we discuss the formation of a new substance, we often refer to the process of compound 复合; it involves a multiplicity 多样性 of elements coming together, sometimes leading to a recombination 重组 of molecular structures.

在化学中，当我们讨论新物质的形成时，通常会提到compound 复合的过程；它涉及多种元素的结合，有时会导致分子结构的recombination 重组。

5.The ecological study revealed a multiplicity 多样性 of species within the habitat, showcasing how different organisms can compound 复合 their efforts in recombination 重组 of resources.

生态研究揭示了栖息地内物种的multiplicity 多样性，展示了不同生物如何在资源的recombination 重组中compound 复合他们的努力。

作文

In the realm of science and technology, the terms compound (化合物), multiplicity (多重性), and recombination (重组) play crucial roles in understanding complex systems. Each of these concepts contributes to a broader comprehension of how elements interact, evolve, and create new forms. This essay aims to explore these three terms, their interconnections, and their significance in various fields, including chemistry, biology, and information technology.Firstly, let us delve into the concept of compound. In chemistry, a compound refers to a substance formed when two or more elements chemically bond together. These compounds exhibit unique properties that differ from the individual elements that constitute them. For example, water (H2O) is a compound made from hydrogen and oxygen. Understanding compounds is fundamental in chemistry as it allows scientists to predict reactions and the behavior of substances under different conditions.On the other hand, multiplicity refers to the existence of multiple forms or variations of a particular entity. In biological contexts, multiplicity can describe the diversity of species within an ecosystem or the variety of genetic traits within a population. This concept emphasizes the richness of life and the importance of genetic variation for adaptation and survival. In technology, multiplicity might refer to the different versions of software or applications that cater to various user needs. Recognizing multiplicity enables researchers and developers to appreciate the complexity and adaptability of systems they work with.The third term, recombination, is particularly significant in genetics and molecular biology. Recombination is the process by which genetic material is rearranged during cell division, leading to new combinations of genes. This phenomenon is essential for evolution, as it introduces genetic diversity, allowing populations to adapt to changing environments. Recombination can also occur in technology, particularly in data processing and algorithm design, where different elements of information are combined to create innovative solutions or products.Now, let's examine how these three concepts interrelate. In a chemical reaction, when elements combine to form a compound, the resulting substance may exhibit a multiplicity of properties depending on its structure and composition. Similarly, in biological systems, the recombination of genes can lead to a rich multiplicity of traits within a population, enhancing its ability to survive and thrive in diverse environments. In the context of technology, the recombination of existing software components can yield new applications that serve multiple purposes, demonstrating the idea of multiplicity in functionality.In conclusion, the terms compound, multiplicity, and recombination represent fundamental concepts that are interwoven across various disciplines. Their significance extends beyond their definitions, as they illustrate the intricate relationships and processes that govern the natural world and technological advancements. By understanding these terms, we gain insights into the complexity and dynamism of systems, whether they be chemical reactions, biological evolution, or innovative technologies. Ultimately, recognizing the importance of compound, multiplicity, and recombination equips us with the knowledge to navigate and influence the multifaceted challenges of our time.

在科学和技术领域，术语compound（化合物）、multiplicity（多重性）和recombination（重组）在理解复杂系统方面起着至关重要的作用。这三个概念各自对元素如何相互作用、演变和创造新形式的更广泛理解做出了贡献。本文旨在探讨这三个术语、它们之间的联系以及它们在化学、生物学和信息技术等各个领域的重要性。首先，让我们深入探讨compound的概念。在化学中，化合物是指当两个或多个元素通过化学键结合在一起形成的物质。这些化合物表现出独特的性质，与构成它们的单个元素有所不同。例如，水（H2O）是由氢和氧组成的化合物。理解化合物是化学中的基础，因为它使科学家能够预测反应以及物质在不同条件下的行为。另一方面，multiplicity指的是某一特定实体存在多种形式或变体。在生物学背景下，多重性可以描述生态系统内物种的多样性或群体内遗传特征的多样性。这个概念强调了生命的丰富性以及遗传变异在适应和生存中的重要性。在技术领域，多重性可能指的是满足不同用户需求的软件或应用程序的不同版本。认识到多重性使研究人员和开发人员能够欣赏他们所研究的系统的复杂性和适应性。第三个术语recombination在遗传学和分子生物学中尤为重要。重组是指在细胞分裂过程中遗传物质重新排列的过程，从而导致基因的新组合。这种现象对进化至关重要，因为它引入了遗传多样性，使种群能够适应不断变化的环境。重组也可以发生在技术中，特别是在数据处理和算法设计中，不同的信息元素被组合以创建创新的解决方案或产品。现在，让我们看看这三个概念是如何相互关联的。在化学反应中，当元素结合形成一个compound时，所产生的物质可能会根据其结构和成分表现出多种multiplicity的特性。同样，在生物系统中，基因的recombination可以导致种群内部丰富的multiplicity特征，从而增强其在多样化环境中的生存和繁荣能力。在技术背景下，现有软件组件的recombination可以产生具有多种功能的新应用程序，展示了功能上的multiplicity的概念。总之，术语compound、multiplicity和recombination代表了在各个学科中交织在一起的基本概念。它们的重要性超越了其定义，因为它们说明了支配自然世界和技术进步的复杂关系和过程。通过理解这些术语，我们获得了对系统复杂性和动态性的洞察，无论它们是化学反应、生物进化还是创新技术。最终，认识到compound、multiplicity和recombination的重要性使我们具备了应对我们时代多方面挑战的知识。