polymerous
简明释义
adj. 多成分的;多数的;多出的
英英释义
Having many parts or segments; composed of multiple units or elements. | 具有多个部分或段落;由多个单元或元素组成。 |
单词用法
同义词
| 多体的 | The organism is described as multimerous due to its complex structure. | 由于其复杂的结构,该生物被描述为多体的。 | |
| 多部分的 | In botany, a many-parted flower can be referred to as polymerous. | 在植物学中,可以将多部分的花称为多体花。 |
反义词
例句
1.In zoology, certain species are classified as polymerous due to their segmented bodies.
在动物学中,某些物种由于其分段的身体而被归类为多聚的。
2.The polymerous nature of the insect's antennae allows for better sensory perception.
昆虫触角的多聚的特性使其能够更好地感知环境。
3.The term polymerous is often used in botany to describe flowers with numerous stamens.
术语多聚的常用于植物学中,描述具有众多雄蕊的花朵。
4.Many plants exhibit polymerous structures, which are characterized by multiple parts or segments.
许多植物表现出多聚的结构,其特征是具有多个部分或段落。
5.Researchers are studying polymerous compounds to develop new materials with unique properties.
研究人员正在研究多聚的化合物,以开发具有独特性质的新材料。
作文
The world around us is filled with fascinating structures and materials, many of which are governed by the principles of chemistry and biology. One term that often arises in discussions about complex biological systems is polymerous, which refers to organisms or structures that consist of multiple parts or units. This concept is particularly relevant in the study of polymers, which are large molecules composed of repeating subunits. In nature, we see numerous examples of polymerous entities, from the intricate designs of proteins to the vast networks of carbohydrates. To better understand the significance of polymerous structures, let's consider the role of proteins in living organisms. Proteins are essential macromolecules that perform a variety of functions, including catalyzing biochemical reactions, providing structural support, and facilitating communication between cells. Each protein is made up of long chains of amino acids, which can be thought of as the building blocks of these polymerous structures. The specific sequence and arrangement of these amino acids determine the protein's unique shape and function, highlighting the importance of their polymerous nature.Another example of polymerous structures can be found in carbohydrates, such as starch and cellulose. These polysaccharides are composed of long chains of sugar molecules, making them polymerous in nature. Starch serves as a vital energy reserve for plants, while cellulose provides structural integrity to plant cell walls. The varying arrangements of sugar units in these polymerous carbohydrates result in different properties and functionalities, showcasing the diversity that can arise from simple repeating units.In addition to biological examples, the concept of polymerous structures extends to synthetic materials as well. For instance, plastics are man-made polymers that have revolutionized our daily lives. These materials are composed of long chains of repeating monomers, which can be tailored to achieve desired characteristics such as flexibility, durability, or resistance to chemicals. The versatility of polymerous materials has made them indispensable in various industries, from packaging to construction.Understanding the polymerous nature of both natural and synthetic materials allows scientists and engineers to innovate and create new products that enhance our quality of life. For example, advancements in biopolymers—polymers derived from renewable resources—are paving the way for more sustainable alternatives to traditional plastics. These innovations not only address environmental concerns but also demonstrate the potential of polymerous materials to adapt and evolve in response to human needs.In conclusion, the term polymerous encapsulates a fundamental principle that underlies much of the complexity we observe in both biological and synthetic systems. By recognizing the significance of polymerous structures, we gain a deeper appreciation for the intricacies of life and the potential for innovation in material science. As we continue to explore the world of polymerous entities, we are reminded of the interconnectedness of all things and the endless possibilities that arise from the combination of simple units into complex forms.
我们周围的世界充满了迷人的结构和材料,其中许多都受到化学和生物学原理的支配。一个常常出现在复杂生物系统讨论中的术语是polymerous,它指的是由多个部分或单元组成的生物体或结构。这个概念在聚合物的研究中尤为相关,聚合物是由重复的子单位组成的大分子。在自然界中,我们可以看到许多polymerous实体的例子,从蛋白质的复杂设计到碳水化合物的广泛网络。为了更好地理解polymerous结构的重要性,让我们考虑蛋白质在生物体中的作用。蛋白质是必不可少的大分子,执行各种功能,包括催化生化反应、提供结构支持和促进细胞间的沟通。每种蛋白质都是由长链氨基酸组成的,可以将其视为这些polymerous结构的构建块。这些氨基酸的特定序列和排列决定了蛋白质的独特形状和功能,突显了它们polymerous特性的意义。另一个polymerous结构的例子可以在碳水化合物中找到,如淀粉和纤维素。这些多糖由长链糖分子组成,因此具有polymerous的特性。淀粉作为植物的重要能量储备,而纤维素则为植物细胞壁提供结构完整性。这些polymerous碳水化合物中糖单位的不同排列导致了不同的性质和功能,展示了简单重复单元所能产生的多样性。除了生物学的例子,polymerous结构的概念还扩展到合成材料。例如,塑料是人造聚合物,已彻底改变了我们的日常生活。这些材料由重复单体的长链组成,可以根据需要进行调整,以实现灵活性、耐用性或抗化学性等特性。polymerous材料的多功能性使其在包装、建筑等各个行业中不可或缺。理解自然和合成材料的polymerous特性使科学家和工程师能够创新并创造出提高我们生活质量的新产品。例如,生物聚合物的进步——源自可再生资源的聚合物——正在为传统塑料提供更可持续的替代品铺平道路。这些创新不仅解决了环境问题,还展示了polymerous材料在响应人类需求方面的潜力。总之,术语polymerous概括了一个基本原则,这一原则支撑着我们在生物和合成系统中观察到的复杂性。通过认识polymerous结构的重要性,我们对生命的复杂性和材料科学创新的潜力有了更深的理解。当我们继续探索polymerous实体的世界时,我们被提醒所有事物的相互联系以及从简单单元组合成复杂形式所带来的无限可能性。
