macroaggregated
简明释义
英[ˌmækrəʊˈæɡrɪɡeɪtɪd]美[ˌmækrəˈæɡrɪˌɡeɪtɪd]
大颗粒的
英英释义
Pertaining to a form of aggregation that occurs at a larger scale, often involving the clustering or grouping of particles or entities into larger aggregates. | 指在较大规模上发生的聚合形式,通常涉及将粒子或实体聚集或组合成更大聚合体。 |
单词用法
宏聚合结构 | |
宏聚合形式 | |
宏聚合系统 | |
宏聚合有机物 | |
宏聚合土壤 | |
宏聚合群落 |
同义词
反义词
| 微聚集的 | The microaggregated particles were too small to be seen without a microscope. | 微聚集的颗粒在没有显微镜的情况下是看不见的。 | |
| 分散的 | The dispersed solution allowed for better absorption of nutrients. | 分散的溶液使营养物质的吸收更好。 |
例句
1.The problems that in the existing method the product quality is low and macroaggregated magnesium sulfate heptahydrate can not be produced are resolved.
解决了现有方法存在的产品质量低及不能生产大颗粒七水硫酸镁的问题。
2.The problems that in the existing method the product quality is low and macroaggregated magnesium sulfate heptahydrate can not be produced are resolved.
解决了现有方法存在的产品质量低及不能生产大颗粒七水硫酸镁的问题。
3.In ecological studies, macroaggregated structures are essential for understanding nutrient cycling.
在生态研究中,宏聚集结构对于理解营养循环至关重要。
4.The researchers found that the soil was macroaggregated to improve water retention.
研究人员发现,土壤被宏聚集以改善水分保持能力。
5.The macroaggregated particles in the sediment enhance the habitat for aquatic organisms.
沉积物中的宏聚集颗粒增强了水生生物的栖息地。
6.Farmers often prefer macroaggregated soil because it supports healthier plant growth.
农民通常更喜欢宏聚集的土壤,因为它支持更健康的植物生长。
7.To improve soil structure, the addition of organic matter can lead to more macroaggregated formations.
为了改善土壤结构,添加有机物可以导致更多的宏聚集形成。
作文
In modern scientific research, the term macroaggregated refers to a process where smaller particles or entities come together to form larger aggregates. This concept is particularly significant in fields such as materials science, biology, and environmental studies. Understanding how these aggregates form and behave can lead to advancements in various applications, from drug delivery systems to the development of new materials with enhanced properties.For instance, in the field of biology, macroaggregated structures can be observed in cellular processes. Cells often communicate and interact through signaling molecules that can aggregate into larger complexes. These macroaggregated structures play a crucial role in cellular functions, such as immune responses and tissue repair. By studying these aggregates, researchers can gain insights into how cells work together to maintain homeostasis and respond to external stimuli.Moreover, in environmental science, the concept of macroaggregated particles is vital in understanding soil health and structure. Soil is composed of various particles that can aggregate into larger clumps. These macroaggregated formations are essential for maintaining soil aeration, water retention, and nutrient availability. When soil particles are well-aggregated, plants can thrive, leading to healthier ecosystems. Conversely, when soil loses its macroaggregated structure due to erosion or poor management practices, it can result in decreased fertility and increased vulnerability to droughts and floods.In materials science, the manipulation of macroaggregated structures can lead to the creation of innovative materials with unique properties. For example, researchers are exploring the use of macroaggregated nanoparticles to enhance the strength and durability of construction materials. By controlling the size and distribution of these aggregates, scientists can develop materials that are not only stronger but also lighter and more sustainable.Furthermore, the study of macroaggregated systems is not limited to natural phenomena; it also extends to engineered systems. In the field of nanotechnology, scientists are investigating how macroaggregated forms of nanoparticles can be utilized in various applications, including electronics, catalysis, and energy storage. The ability to control the aggregation process allows for the design of materials with specific functionalities tailored to meet the needs of different industries.In conclusion, the term macroaggregated encompasses a wide range of phenomena across multiple scientific disciplines. From biological systems to environmental contexts and engineered materials, understanding the principles behind aggregation can unlock new possibilities for innovation and sustainability. As research continues to evolve, the significance of macroaggregated structures will undoubtedly play a pivotal role in shaping the future of science and technology. By deepening our comprehension of how these aggregates form and function, we can harness their potential to address some of the most pressing challenges facing our world today.
在现代科学研究中,术语macroaggregated指的是一个过程,其中较小的颗粒或实体聚集在一起形成较大的聚合体。这个概念在材料科学、生物学和环境研究等领域尤其重要。理解这些聚合体如何形成和行为,可以促进从药物输送系统到新材料开发等各种应用的进展。例如,在生物学领域,macroaggregated结构可以在细胞过程中观察到。细胞通常通过可以聚集成更大复合体的信号分子进行通信和相互作用。这些macroaggregated结构在细胞功能中发挥着至关重要的作用,如免疫反应和组织修复。通过研究这些聚合体,研究人员可以深入了解细胞如何协同工作以维持内稳态并对外部刺激做出反应。此外,在环境科学中,macroaggregated颗粒的概念对于理解土壤健康和结构至关重要。土壤由各种颗粒组成,这些颗粒可以聚集成较大的块状物。这些macroaggregated结构对于维持土壤通气性、水分保持和养分可用性至关重要。当土壤颗粒良好聚集时,植物可以茁壮成长,从而导致更健康的生态系统。相反,当土壤因侵蚀或管理不善而失去其macroaggregated结构时,可能会导致肥力下降和对干旱及洪水的脆弱性增加。在材料科学中,对macroaggregated结构的操控可以导致创新材料的创建,这些材料具有独特的性质。例如,研究人员正在探索使用macroaggregated纳米颗粒来增强建筑材料的强度和耐久性。通过控制这些聚合体的大小和分布,科学家可以开发出不仅更强大而且更轻便、更可持续的材料。此外,macroaggregated系统的研究不仅限于自然现象;它还扩展到工程系统。在纳米技术领域,科学家正在研究如何利用macroaggregated形式的纳米颗粒用于各种应用,包括电子产品、催化和能源存储。控制聚合过程的能力使得设计具有特定功能的材料成为可能,以满足不同行业的需求。总之,术语macroaggregated涵盖了多个科学学科中的广泛现象。从生物系统到环境背景以及工程材料,理解聚合背后的原理可以为创新和可持续性打开新的可能性。随着研究的不断发展,macroaggregated结构的重要性无疑将在塑造科学和技术的未来中发挥关键作用。通过加深我们对这些聚合体如何形成和功能的理解,我们可以利用它们的潜力来应对当今世界面临的一些最紧迫的挑战。
