deposition efficiency

简明释义

熔敷率

英英释义

例句

1.The team measured the deposition efficiency 沉积效率 to ensure the quality of the applied layers.

团队测量了沉积效率以确保施加层的质量。

2.The research focused on improving the deposition efficiency 沉积效率 of thin films in semiconductor manufacturing.

该研究集中于提高半导体制造中薄膜的沉积效率。

3.Improving the deposition efficiency 沉积效率 can significantly reduce material waste in production.

提高沉积效率可以显著减少生产中的材料浪费。

4.The laboratory experiments showed that temperature affects the deposition efficiency 沉积效率 of the chemical vapor deposition process.

实验室实验表明，温度影响化学气相沉积过程的沉积效率。

5.By optimizing the spray parameters, we achieved a higher deposition efficiency 沉积效率 in our coating process.

通过优化喷涂参数，我们在涂层过程中达到了更高的沉积效率。

作文

In the field of material science and engineering, understanding the concept of deposition efficiency is crucial for the development of various technologies. Deposition efficiency refers to the effectiveness with which a material is deposited onto a substrate during processes such as chemical vapor deposition (CVD), physical vapor deposition (PVD), or other coating techniques. High deposition efficiency indicates that a larger proportion of the material being deposited actually adheres to the intended surface, while lower efficiency suggests that much of the material may be wasted or lost in the process.The significance of deposition efficiency can be observed in several applications, including semiconductor manufacturing, thin-film solar cells, and protective coatings. In semiconductor fabrication, for instance, achieving high deposition efficiency is essential for producing high-quality films that enhance the performance of electronic devices. When materials are deposited with high efficiency, it leads to improved electrical properties and device reliability.Moreover, in the realm of renewable energy, the production of thin-film solar cells relies heavily on the deposition efficiency of photovoltaic materials. Higher efficiency in the deposition process translates to better energy conversion rates, which is critical for maximizing the output of solar panels. This not only contributes to the overall efficiency of solar energy systems but also reduces the cost of materials used, making renewable energy sources more viable.Another area where deposition efficiency plays a significant role is in the application of protective coatings. Industries often require durable and resilient coatings to protect surfaces from corrosion, wear, and environmental damage. The ability to achieve high deposition efficiency ensures that these coatings are applied uniformly and effectively, thereby extending the lifespan of the underlying materials.To improve deposition efficiency, researchers and engineers explore various factors that influence the deposition process. These factors include temperature, pressure, precursor materials, and the geometry of the deposition equipment. By optimizing these parameters, it is possible to enhance the rate at which materials are deposited and improve the overall quality of the films produced.In conclusion, deposition efficiency is a pivotal concept in the fields of material science and engineering. Its importance spans across different applications, from semiconductor devices to renewable energy technologies and protective coatings. Understanding and improving deposition efficiency not only enhances the performance of materials but also contributes to the sustainability and cost-effectiveness of various industrial processes. As technology continues to advance, the focus on optimizing deposition efficiency will remain a key area of research and development, paving the way for innovations that can lead to more efficient and effective applications in the future.

在材料科学和工程领域，理解沉积效率的概念对于各种技术的发展至关重要。沉积效率指的是在化学气相沉积（CVD）、物理气相沉积（PVD）或其他涂层技术等过程中，材料沉积到基材上的有效性。高沉积效率表示沉积的材料中有较大比例实际附着在预定表面上，而较低的效率则表明许多材料可能在过程中被浪费或损失。沉积效率的重要性可以在多个应用中观察到，包括半导体制造、薄膜太阳能电池和保护涂层。例如，在半导体制造中，实现高沉积效率对于生产高质量薄膜以增强电子设备性能至关重要。当材料以高效率沉积时，会提高电气特性和设备可靠性。此外，在可再生能源领域，薄膜太阳能电池的生产在很大程度上依赖于光伏材料的沉积效率。沉积过程中的高效率转化为更好的能量转换率，这对最大化太阳能电池板的输出至关重要。这不仅有助于太阳能系统的整体效率，还减少了所用材料的成本，使可再生能源更加可行。沉积效率在保护涂层的应用中也扮演着重要角色。工业通常需要耐用且坚韧的涂层，以保护表面免受腐蚀、磨损和环境损害。实现高沉积效率的能力确保这些涂层均匀而有效地施加，从而延长底层材料的使用寿命。为了提高沉积效率，研究人员和工程师探索影响沉积过程的各种因素。这些因素包括温度、压力、前驱体材料和沉积设备的几何形状。通过优化这些参数，可以提高材料沉积的速率，并改善所产生薄膜的整体质量。总之，沉积效率是材料科学和工程领域的一个关键概念。它的重要性跨越不同的应用，从半导体设备到可再生能源技术以及保护涂层。理解和提高沉积效率不仅能提升材料的性能，还能促进各种工业过程的可持续性和成本效益。随着技术的不断进步，优化沉积效率的关注将仍然是研究和开发的关键领域，为未来更高效和有效的应用铺平道路。