adhesiveness

简明释义

英[ædˈhiːzɪvnəs]美[ædˈhiːzɪvnəs]

n. 粘性；粘合度

英英释义

单词用法

同义词

反义词

例句

1.The adhesiveness is an important factor which affects fluid movement.

粘滞性是影响流体运动的一个重要因素。

2.This adhesive has such advantages as low resistance, stable performance and good adhesiveness.

该胶具有电阻率较低，性能稳定，粘接力强等优点。

3.Disclosed is a chloroprene rubber adhesive composition having excellent adhesiveness and heat resistance which does not diffuse formaldehyde.

本发明提供一种粘合性和耐热性均优异、且不释放甲醛的氯丁二烯橡胶粘合剂组合物。

4.I announce adhesiveness, I say it shall be limitless, unloosen'd.

我宣告人的粘着性，我说它将是无限的，永不松扣。

5.After treated by acupuncture, the necrosis areas reduced and the degree of the adhesiveness and infiltration of the inflammatory cells also decreased.

而应用针刺治疗后各组缺血坏死灶范围减小，半影区炎性细胞粘附及浸润的程度明显减轻。

6.The gel properties of the polymerized. SPI, especially the, hardness and adhesiveness of the gel, were greatly improved.

聚合后蛋白凝胶特性，尤其是凝胶硬度和粘性有较显著提高。

7.Scientists are studying the adhesiveness of certain bacteria to develop new medical treatments.

科学家们正在研究某些细菌的粘附性以开发新的医疗治疗方法。

8.The adhesiveness of the surface was tested to ensure it could withstand harsh weather conditions.

对表面的粘附性进行了测试，以确保其能承受恶劣的天气条件。

9.The adhesiveness of the tape is strong enough to hold up heavy objects.

这种胶带的粘附性足够强，可以支撑重物。

10.In cooking, the adhesiveness of rice affects how well it holds together in a dish.

在烹饪中，米饭的粘附性影响它在菜肴中保持在一起的效果。

11.The adhesiveness of the glue made it perfect for repairing broken ceramics.

这种胶水的粘附性使它非常适合修复破损的陶瓷。

作文

In the world of materials science, the concept of adhesiveness plays a crucial role in determining how substances interact with one another. Adhesiveness refers to the ability of different materials to stick together, which is essential in various applications ranging from everyday products to advanced technologies. Understanding adhesiveness can help us appreciate how certain materials bond and how we can manipulate these properties for desired outcomes.For instance, consider the simple act of using glue. When we apply glue to two surfaces, we are relying on the adhesiveness of the glue to create a strong bond between them. The effectiveness of this bond depends on several factors, including the type of materials being glued, the surface texture, and the environmental conditions such as temperature and humidity. A good understanding of adhesiveness allows manufacturers to create adhesives that work well with specific materials, ensuring that products are durable and reliable.In the construction industry, adhesiveness is equally important. For example, when laying tiles, the adhesive used must have sufficient adhesiveness to hold the tiles in place under various conditions. If the adhesive fails, it can lead to costly repairs and safety hazards. Therefore, engineers and architects must select the right materials and adhesives based on their adhesiveness properties to ensure the longevity and safety of structures.Moreover, adhesiveness is not limited to physical materials; it also has implications in biological systems. For instance, cells in our body use adhesiveness to communicate and interact with each other. The adhesiveness of cell membranes is vital for processes such as tissue formation and immune responses. Understanding how cells adhere to one another can lead to advancements in medical treatments and therapies, particularly in the fields of cancer research and regenerative medicine.The study of adhesiveness extends into the realm of nanotechnology as well. At the nanoscale, materials exhibit unique adhesiveness properties that differ significantly from their bulk counterparts. Researchers are exploring these properties to develop new materials with enhanced performance characteristics, such as increased strength or improved thermal conductivity. By manipulating adhesiveness at the nanoscale, scientists hope to create innovative solutions for a wide range of applications, from electronics to energy storage.In conclusion, adhesiveness is a fundamental property that influences how materials interact in various fields, including construction, biology, and nanotechnology. By understanding and harnessing the principles of adhesiveness, we can improve the design and functionality of products and systems that we rely on every day. As we continue to explore the complexities of adhesiveness, we open the door to new possibilities and advancements that can benefit society as a whole.The importance of adhesiveness cannot be overstated. Whether we are gluing two pieces of paper together, constructing a building, or studying cellular interactions, adhesiveness is a key factor that determines success. Embracing the science behind adhesiveness will undoubtedly lead to innovations that enhance our lives in countless ways.

在材料科学的世界中，粘附性的概念在确定物质之间的相互作用时起着至关重要的作用。粘附性指的是不同材料粘合在一起的能力，这在从日常产品到先进技术的各种应用中都是必不可少的。理解粘附性可以帮助我们欣赏某些材料如何结合，以及我们如何操纵这些特性以获得期望的结果。例如，考虑使用胶水的简单行为。当我们将胶水涂抹在两个表面上时，我们依赖胶水的粘附性来在它们之间创造强有力的结合。这种结合的有效性取决于几个因素，包括被粘合材料的类型、表面纹理以及温度和湿度等环境条件。对粘附性的良好理解使制造商能够创造出与特定材料配合良好的粘合剂，从而确保产品的耐用性和可靠性。在建筑行业，粘附性同样重要。例如，在铺设瓷砖时，所使用的粘合剂必须具有足够的粘附性以在各种条件下保持瓷砖的位置。如果粘合剂失效，可能会导致昂贵的维修和安全隐患。因此，工程师和建筑师必须根据材料的粘附性特性选择合适的材料和粘合剂，以确保结构的持久性和安全性。此外，粘附性不仅限于物理材料；它在生物系统中也有影响。例如，我们体内的细胞利用粘附性进行相互沟通和互动。细胞膜的粘附性对组织形成和免疫反应等过程至关重要。了解细胞如何相互粘附可以推动医学治疗和疗法的进步，特别是在癌症研究和再生医学领域。粘附性的研究还扩展到纳米技术领域。在纳米尺度上，材料表现出独特的粘附性特性，这与其块体对应物显著不同。研究人员正在探索这些特性，以开发具有增强性能特征的新材料，例如更高的强度或改善的热导率。通过在纳米尺度上操纵粘附性，科学家希望创造出广泛应用的新解决方案，从电子产品到能源存储。总之，粘附性是一个基本属性，影响着建筑、生物学和纳米技术等各个领域的材料相互作用。通过理解和利用粘附性的原理，我们可以改善我们每天依赖的产品和系统的设计和功能。随着我们继续探索粘附性的复杂性，我们为新的可能性和进步打开了大门，这些进步可以惠及整个社会。粘附性的重要性不容小觑。无论我们是在将两张纸粘在一起、建造一座建筑，还是研究细胞间的相互作用，粘附性都是决定成功的关键因素。拥抱粘附性背后的科学无疑会导致创新，提升我们生活的方方面面。