synangium

简明释义

英[sɪˈnæn.dʒi.əm]美[sɪˈnæn.dʒi.əm]

n. [脊椎] 聚合囊；聚囊粘菌属

复 数 s y n a n g i a

英英释义

单词用法

同义词

反义词

例句

1.The invention discloses a method of preparing controlled hollow gold nanoball based on synangium mold plates.

本发明公开了一种基于聚合型囊泡模板的可控空心纳米金球的制备方法。

2.The invention discloses a method of preparing controlled hollow gold nanoball based on synangium mold plates.

本发明公开了一种基于聚合型囊泡模板的可控空心纳米金球的制备方法。

3.The structure of the synangium is crucial for understanding plant evolution.

了解植物进化的关键在于合生体的结构。

4.In botany, a synangium can refer to a cluster of sporangia.

在植物学中，合生体可以指一簇孢子囊。

5.Researchers are studying the synangium of ferns to learn more about their reproduction.

研究人员正在研究蕨类植物的合生体，以了解更多关于它们繁殖的信息。

6.The synangium is often found at the tips of certain plant structures.

某些植物结构的顶部常常会发现合生体。

7.Understanding the function of the synangium can help in agricultural practices.

理解合生体的功能可以帮助农业实践。

作文

The study of biology often reveals fascinating structures within organisms that play crucial roles in their development and function. One such structure is the synangium, which is particularly significant in the life cycle of certain species, especially among plants and some lower organisms. A synangium refers to a specialized group of sporangia that are closely associated with each other, often found in ferns and other vascular plants. Understanding the function and importance of the synangium can provide insights into plant reproduction and evolution. In ferns, for instance, the synangium serves as a key site for spore production. Each sporangium within the synangium can release spores when conditions are favorable, allowing for the propagation of the species. This collective arrangement not only increases efficiency in spore dispersal but also enhances the chances of successful fertilization. The evolutionary significance of the synangium lies in its adaptation to various environmental conditions, showcasing how plants have developed complex reproductive strategies over millions of years. Moreover, studying the synangium can also shed light on the relationships between different plant species. By examining the variations in synangium structures across diverse taxa, scientists can trace the evolutionary lineage and understand how certain traits have been conserved or modified. This comparative analysis is crucial for understanding biodiversity and the ecological roles that different plants play in their respective environments. In addition to its biological significance, the synangium has implications in ecological studies. For example, the health of fern populations, which rely on the effective functioning of the synangium, can be an indicator of ecosystem health. Changes in the abundance or structure of synangium in a given area may reflect changes in environmental conditions, such as climate change or habitat destruction. Conservation efforts aimed at protecting fern habitats must take into account the vital role of the synangium in maintaining these populations. Furthermore, the concept of the synangium extends beyond just ferns. In some gymnosperms and angiosperms, similar structures can be observed, albeit with variations in form and function. These adaptations illustrate the versatility of the synangium concept in the plant kingdom, emphasizing its importance across different groups of plants. Researchers continue to explore the genetic and molecular mechanisms underlying the formation and function of the synangium, which could lead to advancements in agricultural practices and crop improvement. In conclusion, the synangium is much more than just a biological term; it represents a critical component of plant life that has significant implications for ecology, evolution, and conservation. By enhancing our understanding of the synangium, we can better appreciate the intricate web of life that sustains our planet. As we face global challenges such as climate change and biodiversity loss, recognizing the importance of structures like the synangium will be essential in developing strategies for sustainable management and conservation of our natural resources.

生物学的研究常常揭示出有机体内部的迷人结构，这些结构在其发展和功能中发挥着至关重要的作用。其中一个这样的结构是synangium，它在某些物种的生命周期中尤其重要，特别是在植物和一些低等生物中。synangium指的是一组紧密相关的特化孢子囊，通常在蕨类植物和其他维管植物中发现。理解synangium的功能和重要性可以为植物的繁殖和进化提供见解。 例如，在蕨类植物中，synangium作为孢子生产的关键场所。每个synangium中的孢子囊在条件适宜时可以释放孢子，从而使物种得以繁衍。这种集体排列不仅提高了孢子的传播效率，还增强了成功受精的机会。synangium的进化意义在于其对各种环境条件的适应，展示了植物如何在数百万年中发展出复杂的繁殖策略。 此外，研究synangium还可以揭示不同植物物种之间的关系。通过检查不同分类群中synangium结构的变化，科学家可以追踪进化谱系，并理解某些特征是如何被保留或修改的。这种比较分析对于理解生物多样性以及不同植物在各自环境中所扮演的生态角色至关重要。 除了生物学意义外，synangium在生态研究中也具有重要意义。例如，依赖于synangium有效功能的蕨类植物种群的健康，可以作为生态系统健康的指标。在特定区域内synangium的丰度或结构变化可能反映环境条件的变化，如气候变化或栖息地破坏。旨在保护蕨类植物栖息地的保护工作必须考虑到synangium在维持这些种群中的重要作用。 此外，synangium的概念不仅限于蕨类植物。在一些裸子植物和被子植物中，也可以观察到类似的结构，尽管在形式和功能上有所不同。这些适应性说明了synangium概念在植物王国中的多样性，强调了其在不同植物群体中的重要性。研究人员继续探索形成和功能的遗传和分子机制，这可能会导致农业实践和作物改良的进步。 总之，synangium不仅仅是一个生物学术语；它代表了植物生命的一个关键组成部分，对生态、进化和保护具有重要意义。通过加深我们对synangium的理解，我们可以更好地欣赏维持我们星球生存的复杂生命网络。当我们面临气候变化和生物多样性丧失等全球挑战时，认识到像synangium这样的结构的重要性，对于制定可持续管理和保护自然资源的战略至关重要。