electric focusing

简明释义

电聚焦

英英释义

例句

1.In electron microscopy, electric focusing is crucial for achieving high-resolution images.

在电子显微镜中，电聚焦 对于获得高分辨率图像至关重要。

2.The design of the particle accelerator relies heavily on electric focusing to direct the beam accurately.

粒子加速器的设计在很大程度上依赖于 电聚焦 来准确引导束流。

3.The application of electric focusing in mass spectrometry allows for better ion detection.

在质谱法中应用 电聚焦 可以更好地检测离子。

4.Researchers are developing new techniques to enhance electric focusing in ion beams.

研究人员正在开发新技术以增强离子束中的 电聚焦。

5.By using electric focusing, we can improve the efficiency of our laser systems.

通过使用 电聚焦，我们可以提高激光系统的效率。

作文

In the realm of modern technology, the term electric focusing refers to a method used in various fields such as optics and electronics to manipulate and control the path of electric fields. This technique is essential for enhancing the performance of devices like electron microscopes and particle accelerators. By employing electric focusing (电聚焦), engineers can achieve a higher resolution in imaging and more accurate measurements in experiments. The principle behind electric focusing lies in the ability to direct charged particles through the use of electric fields. When an electric field is applied, it influences the trajectory of charged particles, allowing them to converge at a specific point. This convergence is crucial for applications that require precision, such as in the development of advanced imaging systems. One of the most significant applications of electric focusing is found in electron microscopy. In this context, the technique allows scientists to focus electron beams onto a sample with incredible accuracy. The result is a detailed image at the atomic level, enabling researchers to study materials and biological specimens in ways that were previously unimaginable. Without electric focusing (电聚焦), the resolution of these images would be significantly lower, limiting our understanding of the microscopic world. Moreover, electric focusing plays a vital role in particle accelerators, where charged particles are accelerated to high speeds before colliding with one another. The focusing of these particles using electric fields is critical to achieving the necessary conditions for successful collisions, which can lead to groundbreaking discoveries in physics. For instance, experiments conducted at facilities like CERN rely heavily on electric focusing to ensure that particle beams remain tightly focused throughout the acceleration process. In addition to scientific applications, electric focusing has potential uses in medical technologies. For example, in radiation therapy, precise targeting of cancer cells is essential to minimize damage to surrounding healthy tissues. By utilizing electric focusing (电聚焦) techniques, doctors can enhance the accuracy of radiation delivery, improving treatment outcomes for patients. As technology continues to advance, the importance of electric focusing will likely grow. Researchers are constantly exploring new ways to refine this technique, seeking to improve its efficiency and effectiveness. Innovations in materials science, for instance, may lead to the development of better electrodes and electric field configurations, further enhancing the capabilities of electric focusing. In conclusion, the concept of electric focusing is a cornerstone of many modern technological advancements. Its ability to control and direct electric fields has profound implications across various fields, from microscopy to particle physics and even medicine. As we continue to push the boundaries of what is possible, electric focusing (电聚焦) will undoubtedly play a pivotal role in shaping the future of technology and science.