oxide isolated island

简明释义

氧化物隔离岛

英英释义

例句

1.During the experiment, the team successfully created an oxide isolated island 氧化物孤立岛 on a silicon substrate.

在实验过程中，团队成功地在硅基底上创建了一个氧化物孤立岛。

2.The researchers observed that the oxide isolated island 氧化物孤立岛 had a unique morphology that enhanced conductivity.

研究人员观察到，氧化物孤立岛 具有独特的形态，增强了导电性。

3.In the study of semiconductor materials, the formation of an oxide isolated island 氧化物孤立岛 can significantly affect the electrical properties.

在半导体材料的研究中，氧化物孤立岛 的形成可以显著影响电气特性。

4.Characterizing the oxide isolated island 氧化物孤立岛 is crucial for understanding its electronic properties.

表征氧化物孤立岛 对于理解其电子特性至关重要。

5.The presence of an oxide isolated island 氧化物孤立岛 can lead to localized strain in the material.

存在氧化物孤立岛 可能导致材料中的局部应变。

作文

In the field of materials science, the term oxide isolated island refers to a specific structural formation that occurs when oxide materials form discrete, non-continuous regions on a substrate. This phenomenon is particularly significant in the study of thin films and nanostructures, where the behavior of materials at the microscopic level can lead to unique electrical, optical, and mechanical properties. Understanding the concept of oxide isolated island is crucial for researchers working on advanced materials for applications such as semiconductors, catalysis, and energy storage. The formation of oxide isolated islands typically occurs during the deposition of oxide films, where factors such as temperature, pressure, and the rate of deposition play critical roles. When conditions are favorable, the oxide material does not spread uniformly across the substrate; instead, it aggregates into small clusters or islands. These islands can vary in size and shape, depending on the specific materials used and the environmental conditions during deposition. One of the most interesting aspects of oxide isolated islands is their impact on the electronic properties of the materials. For example, when these islands form on a semiconductor surface, they can create localized states that affect charge carrier mobility. This can lead to enhanced performance in electronic devices, making the study of these structures highly relevant in the development of next-generation transistors and sensors. Moreover, the oxide isolated island structure can also influence catalytic activity. In heterogeneous catalysis, the active sites for chemical reactions often reside at the edges or interfaces of these islands. By controlling the size and distribution of the islands, researchers can optimize the catalytic efficiency of materials, which is vital for processes such as fuel cell operation and environmental remediation. In addition to their practical applications, oxide isolated islands also provide a fascinating subject for fundamental research. Scientists use various techniques, such as scanning tunneling microscopy (STM) and atomic force microscopy (AFM), to visualize and manipulate these structures at the nanoscale. Through such studies, they can gain insights into the mechanisms of nucleation and growth of oxide materials, furthering our understanding of material behavior on a fundamental level. In conclusion, the concept of oxide isolated island is integral to the advancement of materials science. By studying these unique structures, researchers can unlock new possibilities in technology and engineering. Whether it is enhancing the performance of electronic devices or improving catalytic processes, the implications of oxide isolated islands extend far beyond basic research, paving the way for innovations that could transform various industries. As we continue to explore the nanoscale world, the importance of understanding phenomena like oxide isolated islands will only grow, highlighting the need for ongoing research and development in this exciting field.

在材料科学领域，术语氧化物孤立岛指的是一种特定的结构形成，当氧化物材料在基底上形成离散的、不连续的区域时，就会出现这种现象。这一现象在薄膜和纳米结构的研究中尤为重要，因为材料在微观层面的行为可以导致独特的电气、光学和机械性质。理解氧化物孤立岛的概念对于从事先进材料应用研究的研究人员至关重要，例如半导体、催化剂和能源存储。氧化物孤立岛的形成通常发生在氧化膜沉积过程中，其中温度、压力和沉积速率等因素起着关键作用。当条件适宜时，氧化材料不会均匀地覆盖基底；相反，它会聚集成小的簇或岛屿。这些岛屿的大小和形状可能会有所不同，具体取决于所使用的材料和沉积过程中的环境条件。氧化物孤立岛的一个有趣方面是它们对材料电子性质的影响。例如，当这些岛屿在半导体表面形成时，它们可能会创建局部态，从而影响载流子的迁移率。这可能导致电子设备性能的提升，因此对这些结构的研究在下一代晶体管和传感器的发展中具有高度相关性。此外，氧化物孤立岛结构还可以影响催化活性。在异相催化中，化学反应的活性位点通常位于这些岛屿的边缘或界面上。通过控制岛屿的大小和分布，研究人员可以优化材料的催化效率，这对于燃料电池操作和环境修复等过程至关重要。除了实际应用外，氧化物孤立岛也为基础研究提供了一个迷人的主题。科学家们使用各种技术，如扫描隧道显微镜（STM）和原子力显微镜（AFM），在纳米尺度上可视化和操控这些结构。通过这样的研究，他们可以深入了解氧化物材料的成核和生长机制，进一步加深我们对材料行为的基本理解。总之，氧化物孤立岛的概念是材料科学进步的核心。通过研究这些独特的结构，研究人员可以解锁技术和工程的新可能性。无论是增强电子设备的性能，还是改善催化过程，氧化物孤立岛的影响远远超出基础研究，为可能改变各个行业的创新铺平了道路。随着我们继续探索纳米世界，理解像氧化物孤立岛这样的现象的重要性只会增加，突显出在这一令人兴奋的领域中持续研究和发展的必要性。