active emitting material

简明释义

1. 放射活性材料; 2. 活性发射材料;

英英释义

例句

1.In our lab, we synthesized a novel active emitting material that shows promise for use in flexible displays.

在我们的实验室中，我们合成了一种新型的有源发射材料，在柔性显示器中展现出潜力。

2.The research focused on the development of new types of active emitting material for organic light-emitting diodes.

该研究集中于开发新型的有源发射材料用于有机发光二极管。

3.The efficiency of the active emitting material directly impacts the brightness of the LED lights.

该有源发射材料的效率直接影响LED灯的亮度。

4.The latest findings suggest that the composition of the active emitting material can enhance color purity in displays.

最新的研究结果表明，有源发射材料的成分可以增强显示器中的色彩纯度。

5.Researchers are exploring the use of active emitting material in solar cells to improve energy conversion rates.

研究人员正在探索在太阳能电池中使用有源发射材料以提高能量转换率。

作文

In the field of modern technology, particularly in optoelectronics, the term active emitting material refers to substances that are capable of converting electrical energy into light. These materials are crucial for the development of various devices such as LEDs (light-emitting diodes), lasers, and displays. Understanding how active emitting material works is essential for anyone interested in the advancements of electronic devices that rely on light emission.The basic principle behind active emitting material lies in its ability to emit photons when energized. This process occurs when electrons within the material absorb energy and move to a higher energy level. When these electrons return to their original state, they release energy in the form of light. The efficiency and color of the emitted light depend significantly on the type of active emitting material used.For instance, organic compounds are commonly used as active emitting material in organic LEDs (OLEDs). These materials can produce vibrant colors and are flexible, making them ideal for various applications, including television screens and smartphone displays. On the other hand, inorganic semiconductors, such as gallium arsenide, are often used in laser diodes. These materials provide high efficiency and are widely used in telecommunications and medical devices.The choice of active emitting material is critical for optimizing the performance of electronic devices. Researchers continually explore new materials to enhance light emission efficiency, reduce energy consumption, and improve color quality. Innovations in nanotechnology have also led to the development of quantum dots, which are tiny semiconductor particles that can serve as active emitting material. Quantum dots have unique optical properties that allow for precise control over the color of light emitted, making them highly desirable for next-generation display technologies.Moreover, understanding the properties of active emitting material also plays a significant role in sustainability. As the world shifts towards energy-efficient technologies, the demand for materials that can produce light with minimal energy input increases. By improving the efficiency of active emitting material, manufacturers can create devices that not only last longer but also consume less power, contributing to a greener planet.In conclusion, the concept of active emitting material is fundamental in the realm of optoelectronics. It encompasses a wide range of substances that convert electrical energy into light, playing a vital role in the functionality of many modern devices. As technology continues to evolve, the exploration and enhancement of active emitting material will undoubtedly lead to more efficient, sustainable, and innovative solutions in various fields. Understanding this concept is crucial for anyone looking to delve into the future of technology and its impact on our daily lives.

在现代技术领域，特别是在光电电子学中，术语活性发光材料指的是能够将电能转换为光的物质。这些材料对于开发各种设备至关重要，如LED（发光二极管）、激光器和显示器。理解活性发光材料的工作原理对于任何对依赖光发射的电子设备进步感兴趣的人来说都是必不可少的。活性发光材料的基本原理在于其在被激励时发出光子的能力。当材料中的电子吸收能量并移动到更高的能级时，这一过程就会发生。当这些电子返回到它们的原始状态时，它们以光的形式释放能量。发光的效率和颜色在很大程度上取决于所使用的活性发光材料的类型。例如，有机化合物通常用作有机LED（OLED）中的活性发光材料。这些材料可以产生鲜艳的颜色，并且具有柔韧性，使其非常适合用于电视屏幕和智能手机显示等各种应用。另一方面，无机半导体，如砷化镓，通常用于激光二极管。这些材料提供高效率，广泛应用于电信和医疗设备。选择活性发光材料对于优化电子设备的性能至关重要。研究人员不断探索新材料，以提高光发射效率、降低能耗和改善颜色质量。纳米技术的创新也导致了量子点的发展，量子点是可以作为活性发光材料的微小半导体颗粒。量子点具有独特的光学特性，允许精确控制发射光的颜色，使其成为下一代显示技术的高度理想材料。此外，理解活性发光材料的特性在可持续发展中也起着重要作用。随着世界向节能技术转型，对能够以最小能量输入产生光的材料的需求增加。通过提高活性发光材料的效率，制造商可以创造出不仅使用寿命更长而且消耗更少电力的设备，为保护地球做出贡献。总之，活性发光材料的概念在光电电子学领域是基础性的。它涵盖了一系列将电能转换为光的物质，在许多现代设备的功能中发挥着至关重要的作用。随着技术的不断发展，活性发光材料的探索和增强无疑将导致各个领域更高效、可持续和创新的解决方案。理解这一概念对于任何希望深入了解技术未来及其对我们日常生活影响的人来说都是至关重要的。