photoconductive

简明释义

英[fəʊtəʊkənˈdʌktɪv]美[ˈfoʊtoʊkənˈdʌktɪv]

adj. 光电导的；光敏的

英英释义

单词用法

同义词

反义词

例句

1.The adhesive can bond and package all kinds of photoconductive fiber communication apparatus such as coupler et al.

可用于耦合器等光纤通讯器件的粘接封装。

2.In the paper, the main factors that determine the performance of photoconductive infrared detector are discussed.

文中讨论了决定光导型探测器性能的主要因素。

3.Improvement of high frequency photoconductive decay technique for measuring silicon minority carrier lifetime is described.

本文介绍高频光电导衰减法硅单晶少子寿命测试技术的改进。

4.A new type of photoconductive target is put forward in this paper and it can be adopted as the target of high definition camera tube.

本文提出的新型光电导靶，可以用作高清晰度电视摄象管的靶。

5.For longer wavelengths a number of extrinsic photoconductive devices exist.

对于更长的波长，有许多非本征光电导器件可用。

6.The work has a certain reference to improve the THz radiation power from photoconductive antenna and the design of antenna structure.

该工作对提高光电导天线辐射太赫兹波的功率和天线的设计具有一定的借鉴意义。

7.Phthalocyanine compounds is a new kind of organic photoconductive materials.

酞菁类化合物是一类新型的有机光电导材料。

8.In accordance with simulation results, the characteristics parameters of photoconductive antenna were calculated.

并结合模拟结果对光电导天线的特性参数进行了计算。

9.The new sensor uses a photoconductive technology that enhances its sensitivity to light.

新传感器使用了一种光导电技术，增强了其对光的敏感性。

10.In our experiment, we found that the photoconductive material reacted quickly to changes in light intensity.

在我们的实验中，我们发现该光导电材料对光强度变化反应迅速。

11.The photoconductive layer in the device allows it to convert light into electrical signals.

设备中的光导电层使其能够将光转换为电信号。

12.Researchers are exploring new photoconductive materials for more efficient solar panels.

研究人员正在探索新的光导电材料，以提高太阳能电池板的效率。

13.The photoconductive properties of this compound make it ideal for use in optical switches.

这种化合物的光导电特性使其非常适合用于光学开关。

作文

The field of electronics has undergone a remarkable transformation over the past few decades, leading to the development of various innovative materials and technologies. One such material that has gained significant attention is the photoconductive (光导电的) material. These materials have the unique ability to change their electrical conductivity when exposed to light, making them essential in numerous applications ranging from photodetectors to solar cells. To understand the significance of photoconductive (光导电的) materials, it is important to explore their properties and how they function. When light photons strike a photoconductive (光导电的) material, they can excite electrons, allowing them to move freely within the material. This increase in the movement of electrons leads to a rise in conductivity, which can be harnessed for various technological purposes. For instance, in photodetectors, photoconductive (光导电的) materials are used to convert light signals into electrical signals, enabling devices such as cameras and sensors to capture images and detect changes in light intensity. Moreover, photoconductive (光导电的) materials play a crucial role in the realm of renewable energy. Solar cells, which are designed to convert sunlight into electricity, often utilize photoconductive (光导电的) materials to enhance their efficiency. By optimizing the properties of these materials, researchers can develop solar panels that are not only more efficient but also more cost-effective, making renewable energy sources more accessible to the general public. The versatility of photoconductive (光导电的) materials extends beyond just photodetectors and solar cells. They are also used in various other applications, including displays, lasers, and even in the development of smart textiles. The integration of photoconductive (光导电的) materials into everyday products has the potential to revolutionize the way we interact with technology. For example, imagine clothing that can change color based on the amount of light it receives, thanks to the incorporation of photoconductive (光导电的) fibers. Despite the numerous advantages of photoconductive (光导电的) materials, challenges remain in their widespread adoption. Researchers are continually seeking to improve the efficiency and stability of these materials to ensure their long-term performance. Additionally, there is a need for further exploration into the environmental impact of producing and disposing of photoconductive (光导电的) materials, as sustainability becomes an increasingly important consideration in technology development. In conclusion, the advent of photoconductive (光导电的) materials has opened up a world of possibilities in electronics and renewable energy. Their ability to alter conductivity in response to light has made them invaluable in various applications, from enhancing the performance of solar cells to creating innovative consumer products. As research continues to advance in this field, the future of photoconductive (光导电的) materials looks promising, paving the way for more efficient, sustainable, and interactive technologies.

电子学领域在过去几十年中经历了显著的变革，催生了各种创新材料和技术。其中一种备受关注的材料是光导电的材料。这些材料具有独特的能力，即在光照射下改变其电导率，使其在从光电探测器到太阳能电池等众多应用中至关重要。 为了理解光导电的材料的重要性，探索其特性及其功能是很重要的。当光子照射到光导电的材料上时，它们可以激发电子，使其在材料中自由移动。这种电子运动的增加导致电导率上升，可以用于各种技术目的。例如，在光电探测器中，光导电的材料用于将光信号转换为电信号，使得相机和传感器等设备能够捕捉图像并检测光强变化。 此外，光导电的材料在可再生能源领域也发挥着关键作用。太阳能电池旨在将阳光转化为电力，通常利用光导电的材料来提高其效率。通过优化这些材料的特性，研究人员可以开发出不仅效率更高而且成本更低的太阳能电池，使可再生能源更易于普通大众使用。 光导电的材料的多功能性不仅限于光电探测器和太阳能电池。它们还被广泛应用于显示器、激光器，甚至智能纺织品的开发中。将光导电的材料集成到日常产品中，有潜力彻底改变我们与技术的互动方式。例如，想象一下，衣物可以根据接收到的光线数量改变颜色，这得益于光导电的纤维的应用。 尽管光导电的材料有众多优点，但在其广泛应用中仍然存在挑战。研究人员不断寻求提高这些材料的效率和稳定性，以确保其长期性能。此外，随着可持续性在技术开发中变得越来越重要，还有必要进一步探讨生产和处置光导电的材料的环境影响。 总之，光导电的材料的出现为电子和可再生能源领域打开了一个充满可能性的世界。它们在响应光照变化时改变电导率的能力，使其在各种应用中不可或缺，从提高太阳能电池的性能到创造创新的消费产品。随着这一领域的研究不断进展，光导电的材料的未来看起来充满希望，为更高效、可持续和互动的技术铺平了道路。