deexcitation voltage

简明释义

去激励电压

英英释义

例句

1.The technician calibrated the equipment to ensure the deexcitation voltage was within the optimal range.

技术员对设备进行了校准，以确保去激发电压在最佳范围内。

2.The laser system requires a specific deexcitation voltage to stabilize the output beam.

激光系统需要特定的去激发电压来稳定输出光束。

3.Adjusting the deexcitation voltage can significantly influence the efficiency of the photonic device.

调整去激发电压可以显著影响光子设备的效率。

4.When the deexcitation voltage is too low, the system may not function properly.

当去激发电压过低时，系统可能无法正常工作。

5.In the experiment, we measured the deexcitation voltage to determine the energy levels of the atoms.

在实验中，我们测量了去激发电压以确定原子的能级。

作文

In the realm of physics and electrical engineering, understanding various concepts is crucial for both theoretical and practical applications. One such concept is deexcitation voltage, which plays a pivotal role in the behavior of electronic devices and systems. To grasp the significance of deexcitation voltage, we must first explore what excitation means in this context. Excitation refers to the process whereby an electron in an atom or a semiconductor gains energy and moves to a higher energy level. This can occur due to external stimuli such as electromagnetic radiation or electric fields. However, once the energy source is removed, the excited state cannot be sustained indefinitely. The return of the electron to its original state is known as deexcitation, and the voltage associated with this transition is termed deexcitation voltage.The importance of deexcitation voltage can be observed in various applications, particularly in the field of semiconductors and photonics. For instance, in light-emitting diodes (LEDs), when electrons recombine with holes, they release energy in the form of photons. The energy associated with this recombination is closely linked to the deexcitation voltage. Understanding the deexcitation voltage helps engineers design more efficient LEDs by optimizing the materials used, thereby enhancing their brightness and reducing power consumption.Furthermore, in laser technology, the concept of deexcitation voltage is equally significant. Lasers operate by stimulating atoms or molecules to emit coherent light. The deexcitation process in lasers is critical because it determines the efficiency and output of the laser. By controlling the deexcitation voltage, scientists can manipulate the characteristics of the emitted light, including its wavelength and intensity. This has vast implications for various industries, including telecommunications, medical devices, and manufacturing.Moreover, the study of deexcitation voltage extends beyond just electronics. In quantum mechanics, the principles governing deexcitation processes are fundamental to understanding phenomena such as fluorescence and phosphorescence. These processes have applications in numerous fields, including biology, where they are used in imaging techniques to visualize cellular structures and processes.In conclusion, the concept of deexcitation voltage is integral to a wide range of scientific and engineering disciplines. It not only provides insight into the behavior of electrons in various materials but also influences the design and functionality of numerous devices that are part of our daily lives. By comprehending deexcitation voltage, researchers and engineers can innovate and improve technologies that rely on the principles of excitation and deexcitation, ultimately leading to advancements in efficiency and performance across multiple sectors.

在物理和电气工程领域，理解各种概念对于理论和实际应用至关重要。其中一个概念是去激发电压，它在电子设备和系统的行为中发挥着关键作用。要掌握去激发电压的重要性，我们首先必须探讨在这个上下文中激发的含义。激发是指原子或半导体中的电子获得能量并移动到更高能级的过程。这可以由于外部刺激如电磁辐射或电场而发生。然而，一旦能量源被移除，激发态不能无限期维持。电子返回其原始状态的过程称为去激发，与此转变相关的电压被称为去激发电压。去激发电压的重要性可以在各种应用中观察到，特别是在半导体和光子学领域。例如，在发光二极管（LED）中，当电子与空穴复合时，它们以光子的形式释放能量。与这种复合相关的能量与去激发电压密切相关。理解去激发电压有助于工程师通过优化所用材料来设计更高效的LED，从而增强其亮度并减少功耗。此外，在激光技术中，去激发电压的概念同样重要。激光通过刺激原子或分子发出相干光来工作。激光中的去激发过程至关重要，因为它决定了激光的效率和输出。通过控制去激发电压，科学家可以操纵发射光的特性，包括波长和强度。这对包括电信、医疗设备和制造业在内的多个行业具有广泛的影响。此外，对去激发电压的研究不仅限于电子学。在量子力学中，支配去激发过程的原理是理解荧光和磷光等现象的基础。这些过程在多个领域中都有应用，包括生物学，在这些领域中，它们用于成像技术，以可视化细胞结构和过程。总之，去激发电压的概念是众多科学和工程学科的核心。它不仅提供了对各种材料中电子行为的洞察，还影响着我们日常生活中许多设备的设计和功能。通过理解去激发电压，研究人员和工程师可以创新和改进依赖激发和去激发原理的技术，最终推动各个行业的效率和性能的进步。