electrokinetic moment

简明释义

电动力矩

英英释义

例句

1.Understanding the electrokinetic moment 电动势矩 helps in designing better drug delivery systems.

理解电动势矩 electrokinetic moment有助于设计更好的药物传递系统。

2.The electrokinetic moment 电动势矩 can influence the separation efficiency in electrophoresis.

在电泳中，电动势矩 electrokinetic moment可以影响分离效率。

3.The researchers measured the electrokinetic moment 电动势矩 of the colloidal particles to understand their behavior in an electric field.

研究人员测量了胶体颗粒的电动势矩 electrokinetic moment以了解它们在电场中的行为。

4.In microfluidics, the control of the electrokinetic moment 电动势矩 is crucial for manipulating fluid flow.

在微流控技术中，控制电动势矩 electrokinetic moment对操控流体流动至关重要。

5.The application of an external voltage can alter the electrokinetic moment 电动势矩 of the system significantly.

施加外部电压可以显著改变系统的电动势矩 electrokinetic moment。

作文

In the realm of physics and engineering, the term electrokinetic moment plays a crucial role in understanding the behavior of charged particles in an electric field. The concept refers to the torque experienced by a dipole moment when subjected to an external electric field. This phenomenon is particularly relevant in various applications, including electrokinetic phenomena in colloidal systems, where particles are suspended in a fluid and influenced by electric fields. The electrokinetic moment can be seen as a measure of how effectively these particles can be manipulated through electrokinetic forces.To grasp the significance of the electrokinetic moment, one must first understand the underlying principles of electrokinetics. Electrokinetics involves the motion of dispersed particles in a fluid under the influence of an electric field. This motion can lead to various effects, such as electrophoresis, where charged particles migrate towards electrodes, and dielectrophoresis, where neutral particles experience forces due to non-uniform electric fields. Both phenomena are governed by the electrokinetic moment, which determines how particles respond to these electric fields.For instance, in the field of biomedical engineering, researchers utilize the electrokinetic moment to develop techniques for manipulating cells and biomolecules. By applying specific electric fields, scientists can control the movement of cells, enabling targeted drug delivery or the separation of different cell types for diagnostic purposes. This application highlights the practical importance of understanding the electrokinetic moment in designing effective biomedical devices.Moreover, the electrokinetic moment has implications beyond just biological systems. In environmental science, it is used to study the behavior of pollutants in water bodies. Understanding how contaminants interact with electric fields can inform remediation strategies, helping to clean up polluted sites more efficiently. By analyzing the electrokinetic moment of various pollutants, researchers can predict their movement and fate in aquatic environments.In conclusion, the concept of electrokinetic moment is essential for comprehending the interactions of charged particles in electric fields. Its applications span across multiple disciplines, including biomedical engineering and environmental science, showcasing its versatility and importance in both theoretical and practical contexts. As technology advances, a deeper understanding of the electrokinetic moment will undoubtedly lead to innovative solutions to complex problems, enhancing our ability to manipulate and control matter at the microscopic level.

在物理和工程领域，术语电动势矩在理解带电粒子在电场中的行为方面起着至关重要的作用。该概念指的是当偶极矩受到外部电场影响时所经历的扭矩。这种现象在各种应用中尤为重要，包括胶体系统中的电动现象，在这种情况下，粒子悬浮在液体中并受到电场的影响。电动势矩可以看作是衡量这些粒子通过电动力有效操控程度的一个指标。要理解电动势矩的重要性，首先必须了解电动学的基本原理。电动学涉及在电场影响下分散粒子在流体中的运动。这种运动可能导致各种效应，例如电泳，其中带电粒子向电极迁移，以及介电泳，其中中性粒子由于不均匀电场而经历力。两种现象都受到电动势矩的支配，这决定了粒子如何响应这些电场。例如，在生物医学工程领域，研究人员利用电动势矩开发操控细胞和生物大分子的技术。通过施加特定的电场，科学家可以控制细胞的运动，使目标药物输送或不同细胞类型的分离成为可能。这一应用突显了理解电动势矩在设计有效生物医学设备中的实际重要性。此外，电动势矩不仅限于生物系统。在环境科学中，它被用来研究污染物在水体中的行为。理解污染物如何与电场相互作用可以为修复策略提供信息，帮助更有效地清理污染地点。通过分析各种污染物的电动势矩，研究人员可以预测它们在水环境中的运动和命运。总之，电动势矩的概念对于理解带电粒子在电场中的相互作用至关重要。它的应用跨越多个学科，包括生物医学工程和环境科学，展示了其在理论和实践背景下的多样性和重要性。随着技术的进步，对电动势矩的更深入理解无疑将导致解决复杂问题的创新解决方案，提高我们在微观层面操控和控制物质的能力。