electroosmosis

简明释义

英[ɪˌlektrəʊɒzˈməʊsɪs]美[ɪˌlektroʊɑːzˈmoʊsɪs]

n. [物化] 电渗，[物化] 电渗透

英英释义

单词用法

同义词

反义词

例句

1.This paper introduced the technology of electroosmosis film used in the production of caustic soda and boiler supply water treatment, its profits, together with the equipment producers.

本文介绍了电渗析膜技术在烧碱生产和锅炉给水处理中的应用效益及其设备生产厂家。

2.This paper introduced the technology of electroosmosis film used in the production of caustic soda and boiler supply water treatment, its profits, together with the equipment producers.

本文介绍了电渗析膜技术在烧碱生产和锅炉给水处理中的应用效益及其设备生产厂家。

3.Deformation induced by this electrical field in cement is the result of temperature difference and the electroosmosis behavior of electrolyte solvent in the porous cement matrix.

电力效应是电致温度差和水泥孔隙中电解质溶液产生电渗的共同结果。

4.High electric drying, high electric thawing and electroosmosis dewatering technology are novel technology, and will initiate new domain in electrostatic application.

高压电场干燥、高压电场解冻和电渗透脱水都是新型技术，将会在静电应用方面掀开崭新的一面。

5.Separation mechanism, manipulation of electroosmosis, mobilization methods, detectors and some problems associated with the determination of samples are discussed.

讨论了毛细管等电聚焦中所涉及的问题，如分离机理、电渗、迁移方法、检测器及其应用。

6.The success rate of porous conductive membrane preparation on fused silica capillary was greatly improved by control of voltage bias and electroosmosis effect.

通过控制电压偏置方向，利用电渗流效应使毛细管多孔导电膜的刻蚀成功率得到显著提高。

7.Therefore, the SDS-PAGE gel extraction combining with electroosmosis and dialysis recycling are good and easy to purify the inclusion body proteins.

因此，SDS - PAGE切胶纯化后电渗、透析回收是纯化重组包涵体蛋白有效、简便的方法。

8.Surface electroosmosis method can reduce coal tangent ial resistance but the pole distribution affects the result of reducing resistance.

表面电渗法可有效地减少煤的切向阻力，但电极分布对电渗效果有很大影响。

9.Surface electroosmosis method can reduce coal tangential resistance but the pole distribution affects the result of reducing resistance.

表面电渗法可有效地减少煤的切向阻力，但电极分布对电渗效果有很大影响。

10.The results show that the fabrication process of the microfluided chip is simplified, and the electroosmosis property is steady.

结果表明，该芯片的制作工艺简单，且电渗性能稳定。

11.The process of electroosmosis is often used in soil remediation to remove contaminants from the ground.

电渗透的过程通常用于土壤修复，以去除地下污染物。

12.In microfluidics, electroosmosis allows for precise control of fluid movement in small channels.

在微流体学中，电渗透允许对小通道内的流体运动进行精确控制。

13.Researchers are exploring the use of electroosmosis in drug delivery systems to enhance absorption.

研究人员正在探索在药物传递系统中使用电渗透以增强吸收。

14.The phenomenon of electroosmosis can significantly impact the efficiency of water filtration processes.

现象电渗透可以显著影响水过滤过程的效率。

15.By applying an electric field, electroosmosis can help in the separation of biological molecules.

通过施加电场，电渗透可以帮助分离生物分子。

作文

Electroosmosis is a fascinating phenomenon that involves the movement of liquid through a porous material under the influence of an electric field. This process has significant implications in various fields, including soil science, biomedical engineering, and environmental remediation. To understand electroosmosis (电渗透), we must first delve into its underlying principles and applications. At its core, electroosmosis (电渗透) occurs when an electric field is applied to a liquid containing charged particles. The liquid, often referred to as an electrolyte, contains ions that are attracted to the electrodes of opposite charge. As the ions move towards the electrodes, they drag along the surrounding liquid, resulting in a flow of the liquid itself. This movement can be harnessed for various practical applications. One of the most notable applications of electroosmosis (电渗透) is in the field of soil remediation. Contaminated sites often pose significant environmental challenges, and traditional methods of remediation can be costly and time-consuming. By applying an electric field to the contaminated soil, electroosmosis (电渗透) can facilitate the movement of pollutants towards collection points. This method not only enhances the efficiency of the cleanup process but also minimizes the disruption to the surrounding environment. In biomedical engineering, electroosmosis (电渗透) plays a crucial role in drug delivery systems. Scientists have developed techniques that utilize this phenomenon to enhance the absorption of drugs through biological membranes. By applying an electric field, the movement of charged drug molecules can be controlled, allowing for targeted and efficient delivery to specific tissues or organs. This has the potential to revolutionize treatment methods for various medical conditions, improving patient outcomes significantly. Moreover, electroosmosis (电渗透) is also relevant in the field of microfluidics, which involves the manipulation of small volumes of fluids. In microfluidic devices, electroosmosis (电渗透) can be used to control fluid flow with high precision. This capability is essential for applications such as lab-on-a-chip technologies, where precise control over chemical reactions and analyses is required. By leveraging electroosmosis (电渗透), researchers can develop more efficient and compact devices for medical diagnostics and other applications. Despite its numerous advantages, there are challenges associated with electroosmosis (电渗透) that need to be addressed. For instance, the efficiency of the process can be affected by factors such as the ionic strength of the solution and the characteristics of the porous material. Understanding these variables is crucial for optimizing electroosmosis (电渗透) in various applications. In conclusion, electroosmosis (电渗透) is a powerful tool that has the potential to transform multiple industries. Its ability to facilitate liquid movement under an electric field opens up new avenues for innovation in environmental science, medicine, and engineering. As research continues to advance our understanding of this phenomenon, we can expect to see even more groundbreaking applications emerge, benefiting society as a whole. By harnessing the principles of electroosmosis (电渗透), we can address some of the pressing challenges we face today, paving the way for a more sustainable and healthier future.

电渗透是一个迷人的现象，涉及在电场的影响下，通过多孔材料移动液体。这个过程在多个领域具有重要意义，包括土壤科学、生物医学工程和环境修复。为了理解electroosmosis（电渗透），我们必须首先深入探讨其基本原理和应用。 从根本上讲，electroosmosis（电渗透）发生在施加电场到含有带电粒子的液体时。该液体通常被称为电解质，包含被吸引到相反电极的离子。当离子向电极移动时，它们会拖动周围的液体，从而导致液体本身的流动。这种运动可以用于各种实际应用。 electroosmosis（电渗透）最显著的应用之一是在土壤修复领域。受污染的场所常常对环境造成重大挑战，传统的修复方法可能成本高昂且耗时。通过对受污染的土壤施加电场，electroosmosis（电渗透）可以促进污染物向收集点的移动。这种方法不仅提高了清理过程的效率，还最小化了对周围环境的干扰。 在生物医学工程中，electroosmosis（电渗透）在药物输送系统中发挥着关键作用。科学家们开发了利用这种现象增强药物通过生物膜吸收的技术。通过施加电场，可以控制带电药物分子的运动，从而实现对特定组织或器官的靶向和高效递送。这有潜力彻底改变各种医疗条件的治疗方法，显著改善患者的结果。 此外，electroosmosis（电渗透）在微流控领域也具有相关性，该领域涉及操纵小体积的液体。在微流控设备中，electroosmosis（电渗透）可用于精确控制液体流动。这种能力对于实验室芯片技术等应用至关重要，其中需要对化学反应和分析进行精确控制。通过利用electroosmosis（电渗透），研究人员可以开发出更高效和紧凑的医疗诊断设备及其他应用。 尽管有许多优点，但与electroosmosis（电渗透）相关的挑战仍需解决。例如，过程的效率可能受到溶液离子强度和多孔材料特性的影响。理解这些变量对于优化electroosmosis（电渗透）在各种应用中的表现至关重要。 总之，electroosmosis（电渗透）是一种强大的工具，具有改变多个行业的潜力。它在电场下促进液体运动的能力为环境科学、医学和工程领域的创新开辟了新的途径。随着研究不断推进我们对这一现象的理解，我们可以期待看到更多突破性的应用出现，造福整个社会。通过利用electroosmosis（电渗透）的原理，我们可以解决今天面临的一些紧迫挑战，为更加可持续和健康的未来铺平道路。