crystalline granule

简明释义

晶粒状块

英英释义

例句

1.The production team adjusted the temperature to promote the formation of larger crystalline granules in the solution.

生产团队调整了温度，以促进溶液中更大晶体颗粒的形成。

2.The medication was formulated with crystalline granules to ensure controlled release of the active ingredient.

该药物采用了晶体颗粒的配方，以确保活性成分的控制释放。

3.The geologist examined a sample containing a crystalline granule to determine its mineral composition.

地质学家检查了一个包含晶体颗粒的样本，以确定其矿物成分。

4.Under the microscope, the crystalline granules appeared as tiny, well-defined structures.

在显微镜下，晶体颗粒看起来像微小的、轮廓分明的结构。

5.In the lab, we synthesized a new compound that formed distinct crystalline granules during the cooling process.

在实验室中，我们合成了一种新化合物，在冷却过程中形成了明显的晶体颗粒。

作文

In the realm of materials science, the term crystalline granule refers to a small, solid particle that exhibits a well-defined crystalline structure. These granules are fundamental in various fields, including pharmaceuticals, ceramics, and electronics. Understanding the properties and behaviors of crystalline granule is crucial for developing materials with specific characteristics. The formation of crystalline granule occurs through a process known as crystallization. During this process, atoms or molecules arrange themselves in a highly ordered structure, resulting in the characteristic shapes of crystals. The size and shape of these granules can significantly influence the physical properties of the material, such as its strength, melting point, and solubility. For instance, in the pharmaceutical industry, the size of crystalline granule can affect the drug's bioavailability and how quickly it dissolves in the body. Moreover, the uniformity of crystalline granule is essential for ensuring consistent performance in applications. In ceramics, for example, the presence of evenly sized granules can enhance the material's durability and resistance to thermal shock. Conversely, irregularly sized granules may lead to weaknesses in the final product. Therefore, controlling the granulation process is critical for manufacturers aiming to produce high-quality materials. The study of crystalline granule also extends to its behavior under different environmental conditions. Factors such as temperature, pressure, and humidity can impact the stability and growth of these granules. Researchers often conduct experiments to observe how crystalline granule reacts to changes in these variables, providing insights that can be applied to various industrial processes. Additionally, advancements in technology have allowed scientists to manipulate the properties of crystalline granule at the nanoscale. Nanocrystalline materials, which consist of grains smaller than 100 nanometers, exhibit unique properties that differ from their larger counterparts. These materials can offer enhanced strength, lighter weight, and improved electrical conductivity, making them valuable in cutting-edge applications such as nanotechnology and renewable energy. In conclusion, the concept of crystalline granule plays a pivotal role in many scientific and industrial domains. From improving drug formulations to enhancing material properties, the understanding and manipulation of these granular structures are essential for innovation. As research continues to evolve, the significance of crystalline granule will likely expand, leading to new discoveries and advancements in various fields. In summary, the importance of crystalline granule cannot be overstated. Its implications reach far beyond mere definitions, impacting the efficiency and effectiveness of numerous products we rely on daily. As we continue to explore the potential of materials at the microscopic level, the study of crystalline granule will remain a cornerstone of materials science, driving progress and innovation across multiple industries.

在材料科学领域，术语crystalline granule指的是一种表现出明确晶体结构的小固体颗粒。这些颗粒在制药、陶瓷和电子等多个领域中都是基础。理解crystalline granule的性质和行为对于开发具有特定特征的材料至关重要。crystalline granule的形成是通过一种称为结晶的过程。在此过程中，原子或分子以高度有序的结构排列，从而形成晶体的特征形状。这些颗粒的大小和形状会显著影响材料的物理性质，例如其强度、熔点和溶解度。例如，在制药行业中，crystalline granule的大小可以影响药物的生物利用度以及其在体内溶解的速度。此外，crystalline granule的一致性对于确保应用中的一致性能至关重要。例如，在陶瓷中，均匀大小颗粒的存在可以增强材料的耐久性和热冲击抵抗力。相反，不规则大小的颗粒可能导致最终产品的弱点。因此，控制颗粒化过程对于旨在生产高质量材料的制造商至关重要。对crystalline granule的研究还扩展到其在不同环境条件下的行为。温度、压力和湿度等因素会影响这些颗粒的稳定性和生长。研究人员经常进行实验，以观察crystalline granule如何对这些变量的变化做出反应，从而提供可以应用于各种工业过程的见解。此外，技术的进步使科学家能够在纳米尺度上操控crystalline granule的性质。纳米晶材料由小于100纳米的晶粒组成，表现出与其较大对应物不同的独特性质。这些材料可以提供增强的强度、更轻的重量和改善的电导率，使其在纳米技术和可再生能源等尖端应用中具有价值。总之，crystalline granule的概念在许多科学和工业领域中发挥着关键作用。从改善药物配方到增强材料性能，对这些颗粒结构的理解和操控对于创新至关重要。随着研究的不断发展，crystalline granule的重要性可能会扩大，导致各个领域的新发现和进展。总之，crystalline granule的重要性不容小觑。它的影响远不止于单纯的定义，影响着我们日常依赖的众多产品的效率和效果。随着我们继续探索微观水平上材料的潜力，对crystalline granule的研究将始终是材料科学的基石，推动着各个行业的进步和创新。