chlorenchyma
简明释义
n. [植] 绿色组织
英英释义
Chlorenchyma is a type of plant tissue that contains chloroplasts and is primarily involved in photosynthesis. | 叶绿组织是一种含有叶绿体的植物组织,主要参与光合作用。 |
单词用法
叶绿组织 | |
叶绿细胞 | |
光合叶绿组织 | |
叶片中的叶绿组织 |
同义词
| 叶肉 | The mesophyll of the leaf is responsible for photosynthesis. | 叶子的叶肉负责光合作用。 | |
| 富含叶绿体的组织 | Chloroplast-rich tissue plays a crucial role in converting sunlight into energy. | 富含叶绿体的组织在将阳光转化为能量中起着至关重要的作用。 |
反义词
| 厚壁组织 | 厚壁组织为植物提供结构支持。 | ||
| 薄壁组织 | 薄壁组织参与储存和代谢功能。 |
例句
1.Soluble hexoses (fructose and glucose), not starch and sucrose, were the major carbon sources for nocturnal malate accumulation in the chlorenchyma.
可溶性已糖(葡萄糖和果糖)是绿色组织中夜间苹果酸累积的主要碳源。
2.Soluble hexoses (fructose and glucose), not starch and sucrose, were the major carbon sources for nocturnal malate accumulation in the chlorenchyma.
可溶性已糖(葡萄糖和果糖)是绿色组织中夜间苹果酸累积的主要碳源。
3.The smallest veins are in direct contact with chlorenchyma, both palisade and spongy tissue.
最小的脉是直接和栅栏组织及海绵组织的绿色组织相联结。
4.The leaf's green color is due to the presence of chlorenchyma, which contains chloroplasts.
叶子的绿色是由于存在叶绿体,它含有叶绿体。
5.In photosynthesis, chlorenchyma plays a crucial role by converting sunlight into chemical energy.
在光合作用中,叶绿体通过将阳光转化为化学能发挥着关键作用。
6.The chlorenchyma cells in the plant's stem help in gas exchange.
植物茎中的叶绿体细胞有助于气体交换。
7.Damage to the chlorenchyma can lead to reduced photosynthetic efficiency.
对叶绿体的损伤会导致光合效率降低。
8.Researchers studied the chlorenchyma to understand its impact on plant growth.
研究人员研究了叶绿体以了解其对植物生长的影响。
作文
In the study of plant biology, understanding the various types of tissues is crucial for comprehending how plants function and thrive in their environments. One such tissue that plays a significant role in photosynthesis is known as chlorenchyma. This specialized type of parenchyma tissue contains chloroplasts, which are the organelles responsible for capturing light energy and converting it into chemical energy through the process of photosynthesis. The presence of chloroplasts gives chlorenchyma its green color, making it an essential component in the leaves and stems of many plants.Chlorenchyma is primarily found in the mesophyll layer of leaves, where it is strategically positioned to maximize exposure to sunlight. This tissue is composed of loosely packed cells that allow for efficient gas exchange, facilitating the entry of carbon dioxide and the release of oxygen during photosynthesis. The structure of chlorenchyma not only supports photosynthesis but also provides mechanical support to the plant, helping it maintain its shape and structure.The importance of chlorenchyma extends beyond just photosynthesis. It also plays a vital role in the overall health and growth of the plant. By producing glucose through photosynthesis, chlorenchyma contributes to the plant's energy reserves, which are essential for growth, reproduction, and responses to environmental stresses. Additionally, the oxygen released during photosynthesis is crucial for the survival of aerobic organisms, including humans, highlighting the interconnectedness of life on Earth.Moreover, the efficiency of chlorenchyma can be influenced by various environmental factors. For instance, light intensity, temperature, and water availability all impact the rate of photosynthesis and, consequently, the functionality of chlorenchyma. Plants have developed adaptations to optimize the performance of this tissue under different conditions. For example, some plants may have thicker layers of chlorenchyma in regions with high light exposure, while others may have a more extensive network of air spaces within the tissue to enhance gas exchange in humid environments.In conclusion, chlorenchyma is a fundamental tissue in plants that is integral to the process of photosynthesis and overall plant health. Its unique structure and function allow for effective light capture and gas exchange, contributing to the plant's ability to produce energy and oxygen. Understanding the role of chlorenchyma not only deepens our knowledge of plant biology but also emphasizes the importance of plants in sustaining life on our planet. As we continue to study and appreciate the complexities of plant tissues like chlorenchyma, we gain insights that can inform conservation efforts and agricultural practices aimed at promoting sustainable ecosystems.
在植物生物学的研究中,理解各种类型的组织对于理解植物如何在其环境中生存和繁茁至关重要。其中一种在光合作用中发挥重要作用的组织被称为氯腺组织。这种特殊类型的薄壁组织含有叶绿体,这些细胞器负责捕捉光能并通过光合作用将其转化为化学能。叶绿体的存在使得氯腺组织呈现绿色,因此它是许多植物的叶子和茎的重要组成部分。氯腺组织主要存在于叶子的中层组织中,在那里它被战略性地放置以最大限度地接触阳光。这种组织由松散排列的细胞组成,允许高效的气体交换,促进二氧化碳的进入和光合作用过程中氧气的释放。氯腺组织的结构不仅支持光合作用,还为植物提供机械支持,帮助其保持形状和结构。氯腺组织的重要性超越了光合作用。它还在植物的整体健康和生长中发挥着至关重要的作用。通过光合作用产生的葡萄糖为植物的能量储备做出了贡献,这对生长、繁殖和应对环境压力至关重要。此外,光合作用过程中释放的氧气对包括人类在内的好氧生物的生存至关重要,突显了地球上生命之间的相互联系。此外,氯腺组织的效率可能会受到各种环境因素的影响。例如,光强度、温度和水分可用性都会影响光合作用的速率,从而影响氯腺组织的功能。植物已经发展出适应性,以优化在不同条件下这一组织的表现。例如,一些植物在光照强烈的地区可能会有更厚的氯腺组织层,而其他植物则可能在潮湿环境中拥有更广泛的气体交换网络。总之,氯腺组织是植物中的一种基本组织,对光合作用和整体植物健康至关重要。其独特的结构和功能使得有效捕获光线和气体交换成为可能,从而促进植物产生能量和氧气。理解氯腺组织的作用不仅加深了我们对植物生物学的认识,也强调了植物在维持地球生命方面的重要性。随着我们继续研究和欣赏像氯腺组织这样的植物组织的复杂性,我们获得的见解可以为保护工作和促进可持续生态系统的农业实践提供信息。
