addition mixed crystal

简明释义

1. 加成固溶伐; 2. 加成混晶;

英英释义

例句

1.In semiconductor manufacturing, the use of addition mixed crystal 添加混合晶体 can enhance the efficiency of electronic devices.

在半导体制造中，使用添加混合晶体可以提高电子设备的效率。

2.The team is experimenting with different compositions of addition mixed crystal 添加混合晶体 to achieve optimal performance.

团队正在尝试不同成分的添加混合晶体以实现最佳性能。

3.The findings suggest that the addition mixed crystal 添加混合晶体 can be used in various applications, including optics.

研究结果表明，添加混合晶体可用于包括光学在内的多种应用。

4.The researchers discovered that the properties of the addition mixed crystal 添加混合晶体 improved significantly under high temperatures.

研究人员发现，在高温下，添加混合晶体的性质显著改善。

5.Understanding the behavior of addition mixed crystal 添加混合晶体 under stress is crucial for material science.

了解添加混合晶体在应力下的行为对于材料科学至关重要。

作文

In the field of materials science, the term addition mixed crystal refers to a type of crystalline structure that is formed when different types of atoms or molecules are incorporated into a single crystal lattice. This phenomenon is not only fascinating but also has significant implications for various applications in technology and industry. Understanding how addition mixed crystal structures form and behave can lead to advancements in fields such as electronics, optics, and even pharmaceuticals.To begin with, let’s explore what exactly constitutes an addition mixed crystal. When two or more different substances are combined, they can sometimes form a solid solution where the distinct components mix at the atomic level. This mixing occurs without the formation of a separate phase, allowing the resulting crystal to exhibit properties that are distinct from those of its individual components. For instance, if we take a simple example of sodium chloride (table salt) and potassium chloride, when these two salts are mixed in the right proportions, they can form a homogeneous solid that retains the cubic crystal structure typical of both substances.The significance of addition mixed crystal lies in their unique properties that arise from the combination of different elements. These properties can include enhanced electrical conductivity, improved mechanical strength, or altered optical characteristics. In electronics, for example, semiconductors often rely on addition mixed crystals to achieve desired electronic properties. By carefully selecting the ratio of different elements, engineers can tailor the material to meet specific performance criteria, which is essential for the development of faster and more efficient electronic devices.Moreover, addition mixed crystals are not limited to inorganic materials. Organic compounds can also form mixed crystals, leading to interesting applications in the field of pharmaceuticals. The solubility and stability of drugs can be significantly affected by their crystalline form. By creating addition mixed crystals with different active pharmaceutical ingredients, researchers can enhance the bioavailability of drugs, ensuring that they are more effective when administered to patients.Furthermore, the study of addition mixed crystals is crucial for understanding phenomena such as phase transitions and thermodynamic stability. As temperature and pressure conditions change, the stability of mixed crystals can vary, leading to transformations that can affect material performance. This knowledge is vital for industries that rely on precise material properties, such as aerospace and automotive engineering, where the integrity and reliability of materials are paramount.In conclusion, the concept of addition mixed crystal plays a pivotal role in modern science and technology. By enabling the combination of different elements into a single crystalline structure, it allows for the creation of materials with tailored properties that can meet the demands of various applications. As research continues to advance in this area, we can expect to see even more innovative uses of addition mixed crystals across different industries, ultimately contributing to technological progress and improved quality of life. Understanding and mastering the formation and behavior of addition mixed crystals will undoubtedly remain a key focus for scientists and engineers alike.

在材料科学领域，术语addition mixed crystal指的是一种晶体结构，当不同类型的原子或分子被纳入单一的晶格中时形成。这种现象不仅令人着迷，而且对技术和工业的各种应用具有重要意义。理解addition mixed crystal结构的形成和行为可以促进电子学、光学甚至制药等领域的进步。首先，让我们探讨一下什么构成了addition mixed crystal。当两种或多种不同的物质结合时，它们有时会形成一种固体溶液，其中不同的成分在原子层面上混合。这种混合发生在没有形成单独相的情况下，使得所得晶体表现出与其各个组成部分不同的特性。例如，如果我们以氯化钠（食盐）和氯化钾为简单例子，当这两种盐以适当比例混合时，它们可以形成一种均匀的固体，保持两种物质典型的立方晶体结构。addition mixed crystal的重要性在于它们由于不同元素的组合而产生的独特性质。这些性质可以包括增强的电导率、改善的机械强度或改变的光学特性。例如，在电子学中，半导体通常依赖于addition mixed crystals来实现所需的电子特性。通过仔细选择不同元素的比例，工程师可以定制材料，以满足特定的性能标准，这对于开发更快、更高效的电子设备至关重要。此外，addition mixed crystals并不限于无机材料。有机化合物也可以形成混合晶体，从而在制药领域产生有趣的应用。药物的溶解度和稳定性可以显著影响其晶体形式。通过创建具有不同活性药物成分的addition mixed crystals，研究人员可以提高药物的生物利用度，确保在给患者使用时更有效。此外，研究addition mixed crystals对于理解相变和热力学稳定性等现象至关重要。随着温度和压力条件的变化，混合晶体的稳定性可能会变化，导致影响材料性能的转变。这一知识对于依赖精确材料属性的行业至关重要，例如航空航天和汽车工程，在这些行业中，材料的完整性和可靠性至关重要。总之，addition mixed crystal的概念在现代科学和技术中发挥着关键作用。通过使不同元素能够组合成单一的晶体结构，它允许创造具有定制属性的材料，以满足各种应用的需求。随着这一领域的研究不断推进，我们可以期待看到addition mixed crystals在不同产业中的更多创新用途，最终促进技术进步和改善生活质量。理解和掌握addition mixed crystals的形成和行为无疑将继续成为科学家和工程师的重点。