adhesive property

简明释义

粘着性质

英英释义

例句

1.When selecting a glue, consider its adhesive property 粘附性能 for different surfaces.

选择胶水时，要考虑其针对不同表面的adhesive property 粘附性能。

2.The adhesive property 粘附性能 of this material allows it to bond well with metals.

这种材料的adhesive property 粘附性能使其能够与金属良好结合。

3.The new tape has excellent adhesive property 粘附性能, making it ideal for packaging.

这种新胶带具有优良的adhesive property 粘附性能，非常适合用于包装。

4.The scientist studied the adhesive property 粘附性能 of various polymers to improve product durability.

科学家研究了各种聚合物的adhesive property 粘附性能，以提高产品的耐用性。

5.In construction, materials with strong adhesive property 粘附性能 are essential for ensuring stability.

在建筑中，具有强大adhesive property 粘附性能的材料对于确保稳定性至关重要。

作文

Adhesive properties are fundamental characteristics that define how materials interact with one another when they come into contact. These properties play a crucial role in various fields, including engineering, biology, and everyday life. Understanding the adhesive property (粘附特性) of substances can lead to innovative applications and improvements in technology and materials science.In engineering, the adhesive property (粘附特性) of materials is essential for the design of structures and components. For instance, in construction, adhesives are used to bond different materials together, such as wood, metal, and glass. The strength of these bonds depends on the adhesive property (粘附特性) of the adhesive itself, as well as the surfaces being bonded. Engineers must consider factors such as surface roughness, cleanliness, and the presence of contaminants when selecting adhesives for specific applications. This careful selection ensures that the final product is durable and reliable.In the field of biology, the adhesive property (粘附特性) of cells is a critical area of study. Cells adhere to each other and to their extracellular matrix through specific molecules known as adhesion proteins. These interactions are vital for tissue formation, wound healing, and immune responses. Researchers are exploring how manipulating the adhesive property (粘附特性) of cells can lead to advancements in regenerative medicine and cancer treatment. By understanding and controlling these properties, scientists hope to develop therapies that can enhance healing or inhibit tumor growth.Everyday life is filled with examples of the adhesive property (粘附特性) in action. From the sticky notes we use to remind ourselves of important tasks to the glue that holds our crafts together, these properties are integral to our daily activities. The effectiveness of adhesives in household products often depends on their adhesive property (粘附特性). For example, some tapes are designed to be removable without leaving residue, while others provide a permanent bond. Understanding these differences allows consumers to choose the right product for their needs.Moreover, advancements in technology have led to the development of new adhesives with enhanced adhesive properties (粘附特性). For example, researchers are working on bio-inspired adhesives that mimic the natural glues produced by organisms such as barnacles and geckos. These innovative materials could revolutionize industries by providing stronger, more efficient bonding solutions that are also environmentally friendly.In conclusion, the adhesive property (粘附特性) of materials is a vital aspect of many scientific and practical applications. Whether in engineering, biology, or everyday life, understanding how substances adhere to one another can lead to significant advancements and improvements. As research continues to explore and exploit these properties, we can expect to see even more innovative uses for adhesives in the future. The study of adhesive properties (粘附特性) will undoubtedly remain an important area of focus across various disciplines, highlighting its relevance and necessity in our world.

粘附特性是定义材料在接触时如何相互作用的基本特征。这些特性在工程、生物学和日常生活等多个领域中起着至关重要的作用。理解粘附特性（adhesive property）可以带来创新应用和技术及材料科学的改进。在工程领域，材料的粘附特性（adhesive property）对结构和组件的设计至关重要。例如，在建筑中，粘合剂用于将不同材料粘合在一起，如木材、金属和玻璃。这些粘合的强度取决于粘合剂本身的粘附特性（adhesive property）以及被粘合表面。工程师在选择特定应用的粘合剂时，必须考虑表面粗糙度、清洁度和污染物的存在等因素。这种仔细的选择确保了最终产品的耐用性和可靠性。在生物学领域，细胞的粘附特性（adhesive property）是一个关键的研究领域。细胞通过称为粘附蛋白的特定分子相互粘附以及与细胞外基质粘附。这些相互作用对于组织形成、伤口愈合和免疫反应至关重要。研究人员正在探索如何操控细胞的粘附特性（adhesive property），以推动再生医学和癌症治疗的进展。通过理解和控制这些特性，科学家希望开发出能够增强愈合或抑制肿瘤生长的疗法。日常生活中充满了粘附特性（adhesive property）的实例。从我们用来提醒自己重要任务的便利贴到固定我们手工艺品的胶水，这些特性是我们日常活动的重要组成部分。家庭产品中粘合剂的有效性通常取决于其粘附特性（adhesive property）。例如，一些胶带被设计为可移除而不留下残留物，而另一些则提供永久性粘合。了解这些差异使消费者能够选择适合自己需求的正确产品。此外，技术的进步导致新型粘合剂的开发，其粘附特性（adhesive property）得到了增强。例如，研究人员正在研发模仿海螺和壁虎等生物产生的天然胶水的生物启发粘合剂。这些创新材料可能会通过提供更强大、更高效的粘合解决方案而彻底改变各个行业，同时也更加环保。总之，材料的粘附特性（adhesive property）是许多科学和实际应用的重要方面。无论是在工程、生物学还是日常生活中，理解物质如何相互粘附可以带来显著的进步和改善。随着研究继续探索和利用这些特性，我们可以期待在未来看到更多创新的粘合剂应用。对粘附特性（adhesive property）的研究无疑将继续成为各个学科的重要关注领域，突显其在我们世界中的相关性和必要性。