lamella thickness

简明释义

薄板厚度

英英释义

例句

1.The study focused on the impact of lamella thickness on the overall strength of the material.

该研究重点关注层片厚度对材料整体强度的影响。

2.Researchers found that variations in lamella thickness could lead to different acoustic properties.

研究人员发现，层片厚度的变化可能导致不同的声学特性。

3.In this experiment, we will analyze how lamella thickness influences heat transfer efficiency.

在这个实验中，我们将分析层片厚度如何影响热传递效率。

4.We need to measure the lamella thickness to ensure the quality of our product.

我们需要测量层片厚度以确保产品质量。

5.Adjusting the lamella thickness can significantly affect the performance of the filter.

调整层片厚度可以显著影响过滤器的性能。

作文

Understanding the concept of lamella thickness is crucial in various fields, particularly in materials science and biology. The term 'lamella' refers to a thin layer or plate, and when we talk about lamella thickness (层厚度), we are discussing the measurement of how thick these layers are in a given material or biological structure. In materials science, lamellae can be found in metals, polymers, and ceramics, where their thickness can significantly influence the properties and performance of the material.For instance, in the study of metallic alloys, lamella thickness plays a vital role in determining the strength and ductility of the alloy. A finer lamella thickness can lead to improved mechanical properties due to the increased surface area that allows for better bonding between the layers. Conversely, if the lamella thickness is too great, it may result in poor performance and lower strength, as the layers may not interact effectively.In biological contexts, lamella thickness is often examined in the structure of cells and tissues. For example, in plant cells, chloroplasts contain thylakoid membranes arranged in stacks known as grana. The lamella thickness of these membranes is essential for efficient photosynthesis, as it affects the light absorption and energy conversion processes. Similarly, in human tissues, the thickness of lamellae in bone structures can influence their overall strength and resilience against fractures.Measuring lamella thickness can be done using various techniques, including microscopy and imaging methods, which allow scientists to visualize and quantify the thickness of these layers accurately. For example, electron microscopy can provide high-resolution images that reveal the fine details of lamellar structures, enabling researchers to analyze their properties in depth.Furthermore, the ability to control and manipulate lamella thickness is an important aspect of modern material engineering. By adjusting the processing conditions during the manufacturing of materials, engineers can tailor the lamella thickness to achieve desired characteristics. This capability is especially relevant in industries such as aerospace, automotive, and electronics, where material performance is critical.In conclusion, the significance of lamella thickness cannot be overstated, as it impacts both the physical properties of materials and the biological functions of living organisms. A deeper understanding of this concept allows researchers and engineers to innovate and improve products across various sectors. Whether in developing stronger materials or enhancing biological functions, mastering the implications of lamella thickness is essential for advancing technology and science. As we continue to explore the intricacies of materials and biology, the study of lamella thickness will undoubtedly remain a key focus area, driving future discoveries and applications.

理解层厚度的概念在多个领域中至关重要，尤其是在材料科学和生物学中。‘层’这个术语指的是一层薄薄的膜或板，当我们谈论层厚度时（层厚度），我们讨论的是在给定材料或生物结构中这些层的厚度测量。在材料科学中，层可以在金属、聚合物和陶瓷中找到，其中它们的厚度会显著影响材料的性能和特性。例如，在金属合金的研究中，层厚度在确定合金的强度和延展性方面起着至关重要的作用。较细的层厚度可以由于增加了表面积而改善机械性能，从而允许层之间更好的结合。相反，如果层厚度过大，可能导致性能不佳和强度降低，因为这些层可能无法有效地相互作用。在生物学背景下，层厚度通常在细胞和组织的结构中进行检查。例如，在植物细胞中，叶绿体包含排列成堆的类囊体膜，称为基粒。这些膜的层厚度对高效的光合作用至关重要，因为它影响光吸收和能量转化过程。类似地，在人体组织中，骨结构中层的厚度可以影响其整体强度和抵抗骨折的韧性。测量层厚度可以使用各种技术，包括显微镜和成像方法，这些方法使科学家能够准确地可视化和量化这些层的厚度。例如，电子显微镜可以提供高分辨率的图像，揭示层状结构的细节，使研究人员能够深入分析其特性。此外，控制和操纵层厚度的能力是现代材料工程的重要方面。通过调整材料制造过程中的处理条件，工程师可以针对所需特性调整层厚度。这一能力在航空航天、汽车和电子等行业尤为相关，因为材料性能至关重要。总之，层厚度的重要性不容小觑，因为它影响材料的物理特性和生物体的生物功能。对这一概念的深入理解使研究人员和工程师能够在各个领域创新和改进产品。无论是在开发更强的材料还是增强生物功能，掌握层厚度的影响对于推动技术和科学的发展至关重要。随着我们继续探索材料和生物学的复杂性，层厚度的研究无疑将保持为一个关键的关注领域，推动未来的发现和应用。