dust-coated electrode

简明释义

薄药皮焊条

英英释义

例句

1.The dust-coated electrode 覆盖尘土的电极 caused a delay in the project's timeline due to its poor performance.

由于性能不佳，覆盖尘土的电极导致项目时间表延误。

2.Regular maintenance is essential to prevent the dust-coated electrode 覆盖尘土的电极 from becoming ineffective.

定期维护是防止覆盖尘土的电极失效的关键。

3.Before starting the experiment, we need to clean the dust-coated electrode 覆盖尘土的电极 to ensure accurate results.

在开始实验之前，我们需要清洁覆盖尘土的电极以确保结果准确。

4.The research team discovered that the dust-coated electrode 覆盖尘土的电极 had significantly reduced conductivity.

研究团队发现，覆盖尘土的电极显著降低了导电性。

5.The technician noticed that the dust-coated electrode 覆盖尘土的电极 was affecting the readings of the machine.

技术员注意到，覆盖尘土的电极正在影响机器的读数。

作文

In the realm of electrochemistry, the concept of a dust-coated electrode plays a crucial role in understanding how various surfaces interact with their environment. An electrode is a conductor through which electricity enters or leaves an object, and when it becomes coated with dust, its performance can be significantly affected. The presence of dust can alter the electrode's conductivity, leading to inaccurate measurements and inefficient reactions. This phenomenon is particularly relevant in industrial settings where precision is paramount. For instance, in processes like electroplating or battery production, a clean electrode is essential for optimal performance. When a dust-coated electrode is used, it may hinder the flow of electrons, resulting in poor quality outcomes. Therefore, regular maintenance and cleaning of electrodes are necessary to ensure their longevity and effectiveness.Moreover, the impact of a dust-coated electrode extends beyond just electrical conductivity. In many applications, such as sensors and biosensors, the electrode's surface properties are critical for the detection of specific analytes. Dust accumulation can create a barrier that prevents the target molecules from reaching the electrode surface, thereby compromising the sensor's sensitivity and selectivity. This is particularly evident in environmental monitoring, where electrodes are exposed to various contaminants. To mitigate these issues, researchers are exploring different materials and coatings that can repel dust while maintaining high conductivity. The study of dust-coated electrodes also opens avenues for further research into nanotechnology and material science. By understanding how dust particles interact with electrode surfaces at the microscopic level, scientists can develop innovative solutions to enhance electrode performance. For example, creating superhydrophobic surfaces that resist dust accumulation could revolutionize the efficiency of electrochemical devices. Furthermore, this research has implications in renewable energy sectors, such as solar cells, where dust accumulation can significantly reduce efficiency. In conclusion, the term dust-coated electrode encapsulates a significant challenge in electrochemistry and related fields. It serves as a reminder of the importance of maintaining clean surfaces for effective electrical conduction and accurate measurements. As technology advances, addressing the issues posed by dust will be vital for improving the performance of various electrochemical systems. The ongoing exploration of new materials and cleaning techniques will undoubtedly lead to breakthroughs that enhance our ability to harness electricity in innovative ways. Ultimately, understanding and managing the effects of a dust-coated electrode will contribute to the development of more efficient and reliable technologies in the future.

在电化学领域，尘埃涂层电极的概念在理解各种表面如何与环境相互作用中发挥着至关重要的作用。电极是通过其进入或离开物体的电流的导体，当它被尘埃覆盖时，其性能可能会受到显著影响。尘埃的存在可以改变电极的导电性，导致测量不准确和反应效率低下。这种现象在工业环境中特别相关，因为精确度至关重要。例如，在电镀或电池生产等过程中，干净的电极对于最佳性能至关重要。当使用尘埃涂层电极时，它可能会阻碍电子的流动，从而导致质量不佳。因此，定期维护和清洁电极是确保其耐用性和有效性的必要条件。此外，尘埃涂层电极的影响不仅限于电导率。在许多应用中，例如传感器和生物传感器，电极的表面特性对特定分析物的检测至关重要。尘埃的积累可能会形成一个屏障，阻止目标分子到达电极表面，从而妨碍传感器的灵敏度和选择性。这在环境监测中尤为明显，因为电极暴露于各种污染物。为了减轻这些问题，研究人员正在探索不同的材料和涂层，这些材料和涂层可以抵御尘埃，同时保持高导电性。对尘埃涂层电极的研究也为进一步研究纳米技术和材料科学开辟了新途径。通过了解尘埃颗粒如何在微观层面上与电极表面相互作用，科学家们可以开发出增强电极性能的创新解决方案。例如，创建超疏水表面以抵抗尘埃积累可能会彻底改变电化学设备的效率。此外，这项研究在可再生能源领域也具有重要意义，例如太阳能电池，尘埃的积累会显著降低效率。总之，术语尘埃涂层电极概括了电化学及相关领域面临的重大挑战。它提醒我们保持表面清洁对于有效电导和准确测量的重要性。随着技术的进步，解决尘埃带来的问题对于提高各种电化学系统的性能至关重要。对新材料和清洁技术的持续探索无疑将导致突破，增强我们以创新方式利用电力的能力。最终，理解和管理尘埃涂层电极的影响将有助于未来更高效、可靠技术的发展。