nervation

简明释义

英[nɜːˈveɪʃ(ə)n]美[nɜːrˈveʃən]

n. 脉状，叶脉；翅脉

英英释义

单词用法

同义词

反义词

例句

1.While it was abundantly expressed in the nervation of the leaves, stem near the inflorescence and base of the root.

然而在幼苗的根基部、靠近花序部位的茎中和叶子的经脉中有大量表达；

2.While it was abundantly expressed in the nervation of the leaves, stem near the inflorescence and base of the root.

然而在幼苗的根基部、靠近花序部位的茎中和叶子的经脉中有大量表达；

3.The study of plant anatomy often involves examining the patterns of nervation in leaves.

植物解剖学的研究通常涉及检查叶片中的脉络模式。

4.In botany, nervation can help identify different species of plants.

在植物学中，脉络可以帮助识别不同种类的植物。

5.The nervation of the leaf is crucial for its photosynthetic efficiency.

叶子的脉络对于其光合作用效率至关重要。

6.Understanding the nervation of a leaf can reveal how it adapts to its environment.

了解叶子的脉络可以揭示它如何适应环境。

7.Different types of plants exhibit varying patterns of nervation.

不同类型的植物表现出不同的脉络模式。

作文

Nervation is a term that refers to the arrangement of veins in a leaf or the distribution of nerves in an organism. This concept is significant in various fields, including botany and biology. Understanding nervation (神经分布) can provide insights into the functionality and adaptability of both plants and animals. In botany, for instance, the pattern of nervation (神经分布) in leaves can indicate how a plant has evolved to optimize its photosynthesis process. Different species exhibit various types of nervation (神经分布), such as parallel, reticulate, or palmate, which can affect how efficiently they capture sunlight and manage water. For example, monocots typically have parallel nervation (神经分布), while dicots often display a branching pattern. This structural diversity not only enhances the plant's ability to thrive in different environments but also plays a crucial role in its overall health and growth. In the context of animal biology, nervation (神经分布) refers to the way nerves are distributed throughout an organism's body. The complexity of this distribution can significantly impact the organism's behavior and physiological responses. For instance, a well-developed nervous system allows for quick reflexes and complex movements, which are essential for survival. The study of nervation (神经分布) in animals can reveal how different species have adapted to their environments over time. For example, certain fish have specialized nerve arrangements that enable them to detect changes in water pressure, aiding in their navigation and predation. Moreover, the concept of nervation (神经分布) extends beyond just anatomical structures; it also encompasses the functional aspects of these systems. In both plants and animals, the arrangement of veins or nerves can influence how effectively resources are utilized. In plants, efficient nervation (神经分布) helps in the distribution of nutrients and water, ensuring that all parts of the plant receive what they need to grow. Similarly, in animals, a well-organized nervous system facilitates communication between different body parts, allowing for coordinated actions and responses to stimuli. Understanding nervation (神经分布) is crucial for researchers and scientists who work in ecology and environmental science. By studying the patterns of nervation (神经分布) in various species, they can gain insights into how organisms interact with their environments and each other. This knowledge can be applied to conservation efforts, helping to protect ecosystems by understanding the relationships between different species and their adaptations. In conclusion, nervation (神经分布) is a vital concept that bridges the fields of botany and biology. It provides a framework for understanding how the arrangement of veins in plants and nerves in animals affects their survival and adaptation. By studying nervation (神经分布), we can appreciate the intricate designs of nature and how these designs play a critical role in the health and functionality of living organisms. As we continue to explore the complexities of life on Earth, the study of nervation (神经分布) will undoubtedly remain a key area of focus, revealing more about the interconnectedness of all living things.

神经分布是一个术语，指的是叶子中脉络的排列或生物体内神经的分布。这个概念在植物学和生物学等多个领域具有重要意义。理解nervation（神经分布）可以为我们提供有关植物和动物功能性及适应性的洞察。例如，在植物学中，叶片中的nervation（神经分布）模式可以表明植物如何进化以优化其光合作用过程。不同的物种表现出各种类型的nervation（神经分布），例如平行、网状或掌状，这可能影响它们捕捉阳光和管理水分的效率。例如，单子叶植物通常具有平行的nervation（神经分布），而双子叶植物则往往显示出分支模式。这种结构多样性不仅增强了植物在不同环境中生存的能力，也在其整体健康和生长中起着至关重要的作用。 在动物生物学的背景下，nervation（神经分布）指的是神经在生物体内的分布方式。这种分布的复杂性可以显著影响生物体的行为和生理反应。例如，发达的神经系统允许快速的反射和复杂的运动，这对生存至关重要。对动物中nervation（神经分布）的研究可以揭示不同物种如何随着时间的推移适应其环境。例如，某些鱼类具有特殊的神经排列，使它们能够检测水压变化，从而有助于导航和捕食。 此外，nervation（神经分布）的概念不仅限于解剖结构，它还包括这些系统的功能方面。在植物和动物中，脉络或神经的排列可以影响资源的有效利用。在植物中，有效的nervation（神经分布）有助于营养和水分的分配，确保植物的各个部分都能获得所需的生长条件。同样，在动物中，良好组织的神经系统促进了不同身体部位之间的交流，使协调的动作和对刺激的反应成为可能。 理解nervation（神经分布）对从事生态学和环境科学的研究人员和科学家至关重要。通过研究各种物种的nervation（神经分布）模式，他们可以深入了解生物体如何与环境及彼此互动。这一知识可以应用于保护工作，帮助通过理解不同物种及其适应之间的关系来保护生态系统。 总之，nervation（神经分布）是一个桥接植物学和生物学的重要概念。它为理解植物中脉络的排列和动物中神经的分布如何影响其生存和适应提供了框架。通过研究nervation（神经分布），我们可以欣赏自然的复杂设计以及这些设计在生物体健康和功能中的关键作用。随着我们继续探索地球上生命的复杂性，nervation（神经分布）的研究无疑将继续成为一个重点领域，揭示更多关于所有生物体之间相互联系的知识。