planarized structure

简明释义

平面型结构

英英释义

例句

1.The planarized structure of the solar panel surface maximizes light absorption and efficiency.

太阳能电池板表面的平面化结构最大化了光的吸收和效率。

2.The semiconductor industry relies heavily on a well-defined planarized structure to ensure optimal performance of microchips.

半导体行业在很大程度上依赖于良好定义的平面化结构以确保微芯片的最佳性能。

3.Research shows that a uniform planarized structure enhances the electrical properties of thin films.

研究表明，均匀的平面化结构增强了薄膜的电气特性。

4.In photolithography, achieving a smooth planarized structure is crucial for accurate pattern transfer.

在光刻中，实现光滑的平面化结构对于准确的图案转移至关重要。

5.The development of a planarized structure can significantly improve the adhesion of subsequent layers in multi-layer devices.

开发平面化结构可以显著改善多层设备中后续层的附着力。

作文

In the realm of materials science and engineering, the term planarized structure is often used to describe a surface that has been treated or engineered to achieve a flat, even profile. This concept is critical in various applications, particularly in the semiconductor industry, where the performance of electronic devices can be significantly influenced by the characteristics of their surfaces. A planarized structure ensures that the layers of materials deposited on top do not suffer from irregularities that could lead to defects in the final product.The process of achieving a planarized structure typically involves several techniques, including chemical-mechanical polishing (CMP), which combines chemical etching with mechanical abrasion to smooth out the surface. This method is essential when fabricating integrated circuits, as it allows for the precise layering of different materials needed to create transistors and other components. Without a well-defined planarized structure, the layers may not adhere properly, leading to electrical failures and reduced performance.Moreover, the importance of a planarized structure extends beyond the semiconductor industry. In fields such as optics, having a flat surface is crucial for the proper functioning of lenses and mirrors. Any imperfections on these surfaces can distort light and affect the quality of images produced. Thus, achieving a planarized structure is vital in ensuring that optical devices perform to their highest potential.Additionally, the concept of planarized structure is also relevant in the context of coatings and thin films. For instance, when applying protective coatings to metals or plastics, a flat surface is necessary to ensure uniform coverage and adhesion. If the underlying material has a rough or uneven texture, the coating may not adhere properly, leading to peeling or flaking over time. Therefore, the preparation of a planarized structure is a key step in many manufacturing processes that require durability and aesthetic appeal.In conclusion, the significance of a planarized structure cannot be overstated. It plays a pivotal role in various industries, from electronics to optics and coatings. Engineers and scientists must continuously strive to improve techniques for achieving and maintaining planarization in their respective fields. As technology advances, the need for more sophisticated planarized structures will only grow, driving innovation and enhancing the performance of countless products we rely on every day. Understanding this concept is essential for anyone involved in material design and fabrication, as it lays the foundation for creating high-quality, reliable products that meet the demands of modern technology.

在材料科学和工程领域，术语平面化结构通常用于描述经过处理或工程设计以实现平坦、均匀轮廓的表面。这个概念在各种应用中至关重要，特别是在半导体行业，电子设备的性能可能会受到其表面特性的显著影响。平面化结构确保上面沉积的材料层没有不规则性，这可能导致最终产品中的缺陷。实现平面化结构的过程通常涉及几种技术，包括化学机械抛光（CMP），该方法结合了化学蚀刻和机械磨损，以平滑表面。这种方法在制造集成电路时至关重要，因为它允许对创建晶体管和其他组件所需的不同材料进行精确分层。如果没有良好的平面化结构，这些层可能无法正确附着，导致电气故障和性能降低。此外，平面化结构的重要性超出了半导体行业。在光学等领域，平坦的表面对于镜头和镜子的正常功能至关重要。这些表面上的任何缺陷都可能扭曲光线并影响产生的图像质量。因此，实现平面化结构对于确保光学设备发挥最高潜力至关重要。此外，平面化结构的概念在涂层和薄膜的背景下也相关。例如，在金属或塑料上应用保护涂层时，平坦的表面是确保均匀覆盖和附着所必需的。如果基础材料具有粗糙或不均匀的纹理，涂层可能无法正确附着，导致随着时间的推移而剥落或脱落。因此，准备平面化结构是许多制造过程中需要耐用性和美观的关键步骤。总之，平面化结构的重要性不容小觑。它在各个行业中发挥着关键作用，从电子到光学和涂层。工程师和科学家必须不断努力改进在各自领域实现和维持平面化的技术。随着技术的进步，对更复杂的平面化结构的需求只会增加，推动创新并提高我们每天依赖的无数产品的性能。理解这一概念对于任何参与材料设计和制造的人来说都是至关重要的，因为它为创建高质量、可靠的产品奠定了基础，以满足现代技术的需求。