cellulose microfibril

简明释义

纤维素微纤丝

英英释义

例句

1.Researchers are studying how cellulose microfibril 纤维素微纤维 can be used to improve the durability of biodegradable plastics.

研究人员正在研究如何利用cellulose microfibril 纤维素微纤维来提高可生物降解塑料的耐久性。

2.The mechanical properties of wood are attributed to the orientation of cellulose microfibril 纤维素微纤维 in the cell walls.

木材的机械性能归因于细胞壁中cellulose microfibril 纤维素微纤维的取向。

3.Advancements in nanotechnology allow for the extraction of cellulose microfibril 纤维素微纤维 for use in high-strength composites.

纳米技术的进步使得可以提取cellulose microfibril 纤维素微纤维用于高强度复合材料。

4.In the paper-making industry, the quality of paper largely depends on the arrangement of cellulose microfibril 纤维素微纤维 within the pulp.

在造纸行业，纸张的质量在很大程度上取决于浆料中cellulose microfibril 纤维素微纤维的排列。

5.The structure of the plant cell wall is primarily composed of cellulose microfibril 纤维素微纤维, providing strength and rigidity.

植物细胞壁的结构主要由cellulose microfibril 纤维素微纤维构成，提供强度和刚性。

作文

Cellulose is one of the most abundant organic polymers on Earth, primarily found in the cell walls of plants. It serves as a crucial structural component that provides strength and rigidity to plant cells. Within the structure of cellulose, there are tiny, thread-like structures known as cellulose microfibrils (纤维素微纤维), which play a pivotal role in determining the physical properties of plant materials. These cellulose microfibrils (纤维素微纤维) are composed of numerous cellulose molecules that are tightly packed together, forming a network that enhances the overall stability and integrity of the plant cell wall.The formation of cellulose microfibrils (纤维素微纤维) is a fascinating process that begins during the synthesis of cellulose in the plant. Enzymes called cellulose synthases work at the plasma membrane of plant cells to produce long chains of glucose units. These chains then aggregate to form cellulose microfibrils (纤维素微纤维), which can vary in size and orientation depending on the type of plant and its growth conditions. The arrangement and density of these cellulose microfibrils (纤维素微纤维) are critical for the mechanical properties of the plant tissue, influencing factors such as tensile strength, flexibility, and resistance to pathogens.In addition to their structural significance in plants, cellulose microfibrils (纤维素微纤维) have garnered attention in various industrial applications. For instance, they are utilized in the production of paper, textiles, and biodegradable plastics. The unique properties of cellulose microfibrils (纤维素微纤维), such as their high surface area and ability to form gels, make them ideal candidates for enhancing the performance of materials in these industries. Researchers are exploring ways to manipulate the structure of cellulose microfibrils (纤维素微纤维) to create innovative products that are both environmentally friendly and effective.Moreover, the study of cellulose microfibrils (纤维素微纤维) is crucial for advancing our understanding of plant biology and ecology. By examining how these structures function and adapt to different environmental stresses, scientists can gain insights into plant resilience and adaptation strategies. This knowledge is particularly important in the context of climate change, where understanding how plants respond to stressors such as drought or increased temperatures can inform conservation efforts and agricultural practices.In conclusion, cellulose microfibrils (纤维素微纤维) are fundamental components of plant cell walls that significantly influence the mechanical properties of plant tissues. Their role extends beyond mere structural support, impacting various industries and contributing to our understanding of plant biology. As research continues to unveil the complexities of cellulose microfibrils (纤维素微纤维), we can anticipate new innovations that harness their unique properties for sustainable development and environmental stewardship.

纤维素是地球上最丰富的有机聚合物之一，主要存在于植物的细胞壁中。它作为一个重要的结构成分，为植物细胞提供强度和刚性。在纤维素的结构中，有一些微小的线状结构被称为纤维素微纤维（cellulose microfibrils），这些结构在决定植物材料的物理特性方面发挥着关键作用。这些纤维素微纤维（cellulose microfibrils）由许多紧密排列的纤维素分子组成，形成一个增强植物细胞壁整体稳定性和完整性的网络。纤维素微纤维（cellulose microfibrils）的形成是一个迷人的过程，始于植物中纤维素的合成。名为纤维素合成酶的酶在植物细胞的质膜上工作，产生长链的葡萄糖单元。这些链随后聚集形成纤维素微纤维（cellulose microfibrils），其大小和取向因植物类型及其生长条件而异。这些纤维素微纤维（cellulose microfibrils）的排列和密度对植物组织的机械性能至关重要，影响诸如抗拉强度、柔韧性和抗病性等因素。除了在植物中的结构重要性外，纤维素微纤维（cellulose microfibrils）在各种工业应用中也引起了关注。例如，它们被用于纸张、纺织品和可生物降解塑料的生产。纤维素微纤维（cellulose microfibrils）独特的特性，如高表面积和形成胶体的能力，使它们成为增强这些行业材料性能的理想候选者。研究人员正在探索操控纤维素微纤维（cellulose microfibrils）结构的方法，以创造出既环保又有效的新产品。此外，研究纤维素微纤维（cellulose microfibrils）对于推进我们对植物生物学和生态学的理解至关重要。通过研究这些结构如何在不同环境压力下发挥作用和适应，科学家们可以深入了解植物的韧性和适应策略。这一知识在气候变化背景下尤为重要，因为了解植物如何应对干旱或温度升高等压力源，可以为保护工作和农业实践提供信息。总之，纤维素微纤维（cellulose microfibrils）是植物细胞壁的基本组成部分，显著影响植物组织的机械性能。它们的作用超越了单纯的结构支持，影响着多个行业，并为我们理解植物生物学做出了贡献。随着研究继续揭示纤维素微纤维（cellulose microfibrils）的复杂性，我们可以期待新的创新，利用其独特特性实现可持续发展和环境保护。