absorption impurity

简明释义

吸收杂质;

英英释义

例句

1.The researchers found that the level of absorption impurity 吸收杂质 in the solution affected the overall efficiency of the experiment.

研究人员发现，溶液中吸收杂质的水平影响了实验的总体效率。

2.In spectroscopy, absorption impurity 吸收杂质 can interfere with the accuracy of the results.

在光谱学中，吸收杂质可能干扰结果的准确性。

3.To improve the quality of the product, they had to reduce the absorption impurity 吸收杂质 in the manufacturing process.

为了提高产品质量，他们必须减少生产过程中吸收杂质的含量。

4.The presence of absorption impurity 吸收杂质 can lead to significant errors in analytical measurements.

存在吸收杂质可能导致分析测量中的重大误差。

5.The team developed a new method to detect absorption impurity 吸收杂质 in various materials.

团队开发了一种新方法来检测各种材料中的吸收杂质。

作文

In the realm of materials science and engineering, the concept of absorption impurity plays a crucial role in understanding the properties and behaviors of various substances. An absorption impurity refers to an unwanted substance that is absorbed into a material, which can significantly alter its characteristics. These impurities can originate from environmental factors or during the manufacturing process, leading to changes in electrical, thermal, or mechanical properties of the material. For instance, when metals are exposed to certain gases or liquids, they may absorb these elements, resulting in absorption impurities that impact their strength and durability.The presence of absorption impurities is particularly significant in the semiconductor industry, where the purity of materials is paramount. Semiconductors require a high level of purity to function effectively; even a minute amount of absorption impurity can degrade their performance. For example, silicon, which is the backbone of most electronic devices, must be free from absorption impurities to ensure optimal conductivity and efficiency. Manufacturers often employ advanced purification techniques to minimize these impurities, ensuring that the final product meets stringent quality standards.Moreover, the study of absorption impurities extends beyond just semiconductors. In the field of chemistry, understanding how different substances interact with solvents can lead to better separation techniques and improved chemical reactions. For instance, in catalysis, the presence of certain absorption impurities can either enhance or hinder the reaction rates, making it essential for chemists to identify and control these variables.Environmental scientists also pay close attention to absorption impurities, especially in the context of pollution and its effects on ecosystems. When pollutants are absorbed by soil or water, they can create absorption impurities that have detrimental effects on plant and animal life. Understanding the mechanisms of absorption helps in developing strategies for remediation and pollution control, ensuring that ecosystems remain healthy and balanced.In conclusion, the significance of absorption impurities spans multiple disciplines, including materials science, chemistry, and environmental science. The ability to understand and manage these impurities is essential for technological advancement and environmental protection. As we continue to explore the intricacies of materials and their interactions, the study of absorption impurities will undoubtedly remain a critical area of research, influencing innovations across various fields. By addressing the challenges posed by absorption impurities, we can pave the way for more efficient materials and cleaner environments, ultimately benefiting society as a whole.

在材料科学和工程领域，吸收杂质的概念在理解各种物质的性质和行为方面发挥着至关重要的作用。吸收杂质指的是被材料吸收的不需要的物质，这可能会显著改变其特性。这些杂质可能源于环境因素或制造过程中的污染，导致材料的电气、热或机械性能发生变化。例如，当金属暴露在某些气体或液体中时，它们可能会吸收这些元素，从而形成影响其强度和耐久性的吸收杂质。在半导体行业，吸收杂质的存在尤为重要，因为材料的纯度至关重要。半导体需要高水平的纯度才能有效工作；即使是微量的吸收杂质也可能降低其性能。例如，硅是大多数电子设备的基础，必须不含吸收杂质以确保最佳的导电性和效率。制造商通常采用先进的净化技术来最小化这些杂质，确保最终产品符合严格的质量标准。此外，吸收杂质的研究不仅限于半导体。在化学领域，理解不同物质与溶剂的相互作用可以导致更好的分离技术和改善化学反应。例如，在催化过程中，某些吸收杂质的存在可能会增强或阻碍反应速率，因此化学家必须识别和控制这些变量。环境科学家也非常关注吸收杂质，尤其是在污染及其对生态系统影响的背景下。当污染物被土壤或水吸收时，它们可能会形成对植物和动物生命有害的吸收杂质。理解吸收机制有助于制定修复和污染控制策略，确保生态系统保持健康和平衡。总之，吸收杂质的重要性跨越多个学科，包括材料科学、化学和环境科学。理解和管理这些杂质的能力对于技术进步和环境保护至关重要。随着我们继续探索材料及其相互作用的复杂性，吸收杂质的研究无疑将继续成为一个关键的研究领域，影响各个领域的创新。通过解决吸收杂质带来的挑战，我们可以为更高效的材料和更清洁的环境铺平道路，最终使整个社会受益。