laser doping

简明释义

激光搀杂

英英释义

例句

1.The team found that laser doping significantly improved the performance of the solar cells.

团队发现激光掺杂显著提高了太阳能电池的性能。

2.In the manufacturing process, laser doping is used to create precise patterns on the silicon wafers.

在制造过程中，激光掺杂用于在硅片上创建精确的图案。

3.The application of laser doping in optoelectronic devices has opened new avenues for research.

在光电设备中应用激光掺杂为研究开辟了新途径。

4.Using laser doping, they were able to control the depth of the doped layer with high precision.

通过使用激光掺杂，他们能够高精度地控制掺杂层的深度。

5.The researchers employed laser doping to enhance the conductivity of the semiconductor material.

研究人员采用激光掺杂来提高半导体材料的导电性。

作文

The advancement of technology has brought about numerous innovations in various fields, one of which is the application of laser techniques in material science. Among these techniques, laser doping plays a crucial role in enhancing the properties of semiconductors and other materials. This process involves the introduction of dopants into a substrate using focused laser beams, allowing for precise control over the doping concentration and depth. By utilizing laser doping (激光掺杂), researchers can manipulate the electrical and optical properties of materials, paving the way for the development of more efficient electronic devices and photonic applications.One of the significant advantages of laser doping is its ability to achieve high spatial resolution. Traditional doping methods often result in uneven distributions of dopants, which can lead to performance inconsistencies in semiconductor devices. However, with laser doping (激光掺杂), the laser can be finely focused to target specific areas of the material, ensuring that the dopants are precisely placed where they are needed. This level of control is particularly beneficial in the fabrication of microelectronic components, where even minor variations can significantly affect device performance.Moreover, laser doping allows for the use of a wider range of dopants compared to conventional methods. The high energy of the laser can effectively introduce dopants that may not easily diffuse into the substrate at lower temperatures. This capability opens up new possibilities for creating materials with tailored properties, such as enhanced conductivity or specific optical characteristics. For instance, laser doping (激光掺杂) has been successfully employed to create high-performance silicon-based photonic devices, which are essential for modern communication technologies.In addition to its technical advantages, laser doping also offers economic benefits. The precision and efficiency of this method can lead to reduced material waste and lower production costs. As industries continue to seek ways to optimize their manufacturing processes, the adoption of laser doping (激光掺杂) is likely to increase, further driving innovation in semiconductor technology.As we look to the future, the potential applications of laser doping are vast. From improving solar cell efficiency to developing next-generation lasers and sensors, this technique holds promise for advancing various technological frontiers. Researchers are continually exploring new materials and combinations of dopants that can be utilized through laser doping (激光掺杂), leading to exciting discoveries and breakthroughs.In conclusion, laser doping represents a significant leap forward in the field of material science. Its ability to provide precise control over doping processes, combined with its versatility and cost-effectiveness, makes it an invaluable tool for researchers and manufacturers alike. As technology continues to evolve, the impact of laser doping (激光掺杂) will undoubtedly be felt across multiple industries, driving progress and innovation in ways we have yet to fully imagine.