nervure

简明释义

英[ˈnɜːvjʊə]美[ˈnɜːrvjʊr]

n. 叶脉；[昆] 翅脉

英英释义

单词用法

同义词

反义词

例句

1.In the foundation of the biomimetic wing's model, the modal optimization method was studied, considering different parameters such as aspect ratio and key node coordinates of wing's nervure.

在此基础上，以翅翼的展弦比和翅脉关键点的坐标为主要参数，使用有限元优化方法，对仿生翅翼的模态优化进行了初步探讨。

2.In the foundation of the biomimetic wing's model, the modal optimization method was studied, considering different parameters such as aspect ratio and key node coordinates of wing's nervure.

在此基础上，以翅翼的展弦比和翅脉关键点的坐标为主要参数，使用有限元优化方法，对仿生翅翼的模态优化进行了初步探讨。

3.The phenomenon, which the newspaper dubbed "Paris Syndrome", was first detailed in the psychiatric journal Nervure in 2004.

《星期日报》将这种现象称之为“巴黎综合症”。2004年，心理学期刊《Nervure》首次提到这一病症。

4.Methods Observing the survival rate and filial generation nervure variation of housefly which treated with ozone.

方法用一定浓度的臭氧对家蝇的卵、蛹、成虫作用一定时间，分别观察其成活率及子代的翅脉变异。

5.The biologist examined the leaf's nervure to understand its vascular system.

生物学家检查了叶子的神经脉以了解其维管系统。

6.In entomology, the nervure patterns on insect wings are crucial for species identification.

在昆虫学中，昆虫翅膀上的神经脉图案对物种鉴定至关重要。

7.Artists often look at the nervure of leaves to replicate natural designs in their work.

艺术家们常常观察叶子的神经脉，以在他们的作品中复制自然设计。

8.The nervure structure can indicate the health of a plant.

该神经脉结构可以指示植物的健康状况。

9.During the dissection, we noted the arrangement of the nervure in various plant species.

在解剖过程中，我们注意到不同植物物种中神经脉的排列。

作文

In the intricate world of biology, the term nervure refers to the veins or rib-like structures found in the wings of insects and the leaves of plants. These structures are not merely decorative; they play a crucial role in the overall functionality and health of the organism. Understanding the significance of nervure can provide insights into various biological processes and the evolution of species. The nervure system in insect wings serves multiple purposes. Firstly, it provides structural support, allowing the wings to maintain their shape and withstand the forces of flight. The arrangement of nervure in the wings varies among different species, reflecting adaptations to their specific environments and lifestyles. For instance, some insects have broad wings with dense nervure, which helps them glide efficiently, while others possess slender wings designed for rapid maneuvering. In plants, nervure refers to the network of veins that transport water, nutrients, and sugars throughout the leaf. This vascular system is essential for photosynthesis, as it ensures that the cells receive the necessary resources to produce energy. The pattern of nervure in leaves also influences their ability to capture sunlight effectively. For example, broad leaves typically have a more complex nervure pattern, which maximizes surface area for light absorption. Furthermore, the study of nervure can reveal much about the evolutionary history of both plants and insects. By examining the similarities and differences in nervure patterns across various species, scientists can trace lineage and understand how different organisms have adapted to their environments over time. This field of study not only enhances our understanding of biodiversity but also informs conservation efforts aimed at preserving delicate ecosystems. Moreover, nervure can serve as an indicator of environmental changes. For instance, alterations in the nervure patterns in certain plant species may signal stress due to climate change or pollution. Monitoring these changes can help researchers develop strategies to mitigate adverse effects on the ecosystem. In conclusion, the concept of nervure is integral to the study of biology, offering insights into the structure and function of both plants and insects. By recognizing the importance of nervure, we can appreciate the complexity of life forms and their interconnections within ecosystems. As we continue to explore the natural world, the knowledge gained from studying nervure will undoubtedly contribute to our understanding of evolution, ecology, and the pressing challenges posed by environmental changes.

在生物学的复杂世界中，术语nervure指的是昆虫翅膀和植物叶片中的脉络或肋状结构。这些结构不仅仅是装饰性的；它们在生物体的整体功能和健康中发挥着至关重要的作用。理解nervure的重要性可以提供对各种生物过程和物种进化的洞察。 昆虫翅膀中的nervure系统具有多重用途。首先，它提供结构支持，使翅膀能够保持形状并抵御飞行时的力量。nervure在翅膀中的排列因不同物种而异，反映出对其特定环境和生活方式的适应。例如，一些昆虫拥有宽大的翅膀，具有密集的nervure，这有助于它们有效滑翔，而其他昆虫则拥有细长的翅膀，旨在快速机动。 在植物中，nervure指的是运输水分、营养物质和糖分的脉络网络。这种维管系统对光合作用至关重要，因为它确保细胞获得必要的资源以产生能量。叶子中的nervure模式也影响其有效捕获阳光的能力。例如，宽大的叶子通常具有更复杂的nervure模式，从而最大化光吸收的表面积。 此外，nervure的研究可以揭示植物和昆虫的进化历史。通过检查不同物种之间nervure模式的相似性和差异，科学家可以追踪谱系，了解不同生物如何随着时间的推移适应其环境。这一研究领域不仅增强了我们对生物多样性的理解，还为保护脆弱生态系统的努力提供了信息。 此外，nervure可以作为环境变化的指标。例如，某些植物物种中nervure模式的变化可能表明由于气候变化或污染导致的压力。监测这些变化可以帮助研究人员制定减轻生态系统不利影响的策略。 总之，nervure的概念对生物学研究至关重要，提供了对植物和昆虫的结构和功能的洞察。通过认识到nervure的重要性，我们可以欣赏生命形式的复杂性及其在生态系统中的相互联系。随着我们继续探索自然世界，从研究nervure中获得的知识无疑将有助于我们对进化、生态学以及环境变化带来的紧迫挑战的理解。