diffusibility

简明释义

英[dɪˌfjuːzəˈbɪlətɪ]美[dɪˌfjʊzəˈbɪləti]

n. 扩散性；扩散率；可传播性

英英释义

单词用法

同义词

反义词

例句

1.The experimental results show that the replacing of the hydroxy groups with acetoxy groups in the resin causes less water uptake, but increases the diffusibility of water in the resin.

实验结果表明，该树脂中的羟基改为乙酸基后可降低树脂的饱和吸水率，并增大水在树脂中的扩散能力。

2.TBT have strong diffusibility and the development trend of systematism, and those characteristics magnify the harm of illegal TBT.

TBT具有扩散性强的特点、体系化的发展趋势，二者均对非法TBT的危害性具有放大效应。

3.A laser optitherm transmission technique for the measurement of material thermal diffusibility is introduced.

介绍利用激光光热透射技术测量材料热扩散率的方法。

4.The experimental results show that the replacing of the hydroxy groups with acetoxy groups in the resin causes less water uptake, but increases the diffusibility of water in the resin.

实验结果表明，该树脂中的羟基改为乙酸基后可降低树脂的饱和吸水率，并增大水在树脂中的扩散能力。

5.Any banking risk is of diffusibility.

银行风险具有扩散性。

6.According to the diffusibility of the photons transmission, numerical solution of photon transmission partial differential equation was deduced with finite element.

依据光子传输的扩散性，用有限元法导出光子传输扩散偏微分方程的数值解。

7.A large quantity of simulation data indicates that, the toggle rules found by this genetical algorithm have good avalanche effects and diffusibility.

通过大量的实验统计数据表明这类演化规则具有良好的雪崩性、扩散性。

8.The calculating results of activation energy show that the diffusibility of nanometer Ni is better than Ni foil in diffusion layer at joints.

通过计算接头处扩散层的激活能可知纳米镍的扩散性能比镍箔的好。

9.The diffusibility of water through membranes is a key factor in osmosis.

水通过膜的扩散性是渗透作用的关键因素。

10.The study of gas diffusibility has important implications for environmental science.

气体的扩散性研究对环境科学具有重要意义。

11.Researchers are examining the diffusibility of various gases in different materials.

研究人员正在检查不同材料中各种气体的扩散性。

12.The diffusibility of nutrients in soil is crucial for plant growth.

土壤中养分的扩散性对植物生长至关重要。

13.In pharmaceuticals, the diffusibility of a drug can affect its absorption rate in the body.

在制药行业，药物的扩散性会影响其在体内的吸收速率。

作文

The concept of diffusibility is crucial in various scientific fields, particularly in chemistry and physics. It refers to the ability of a substance to spread out or disperse in a medium. Understanding diffusibility can help us comprehend how different substances interact with each other and their environment. For example, when a drop of food coloring is added to water, it gradually spreads throughout the liquid. This phenomenon occurs due to the diffusibility of the dye molecules as they move from an area of higher concentration to an area of lower concentration. In biological systems, diffusibility plays a vital role in processes such as respiration and nutrient absorption. Oxygen and carbon dioxide, for instance, diffuse across cell membranes through a process called passive transport. The rate of diffusion depends on several factors, including temperature, concentration gradient, and the size of the molecules involved. Therefore, understanding the diffusibility of gases is essential for studying respiratory physiology.Moreover, the concept of diffusibility extends beyond the natural sciences. In social sciences, we can draw parallels between the diffusion of substances and the spread of ideas or innovations within a society. Just as molecules diffuse through a medium, ideas can permeate communities, influencing behaviors and practices. This analogy highlights the importance of diffusibility not only in a physical sense but also in a metaphorical context.To illustrate this further, consider the diffusion of technology. When a new gadget is introduced, its adoption often follows a pattern similar to that of diffusibility. Early adopters are like the initial molecules that begin to spread in a medium, while the majority of users follow as the technology becomes more accessible and its benefits become apparent. This pattern can be analyzed using models of diffusibility, which help predict how quickly and widely a new innovation will be embraced by the public.In conclusion, diffusibility is a multifaceted concept that bridges various disciplines. Whether we are discussing the movement of particles in a solution, the exchange of gases in biological systems, or the spread of information in society, the principle of diffusibility remains relevant. By understanding this concept, we gain insights into both the physical world and the dynamics of human interaction. As we continue to explore the implications of diffusibility, we can better appreciate the interconnectedness of all things, from the microscopic to the societal level.

“扩散性”这一概念在多个科学领域中至关重要，尤其是在化学和物理学中。它指的是一种物质在介质中扩散或分散的能力。理解“扩散性”可以帮助我们理解不同物质如何相互作用以及与环境的关系。例如，当一滴食用色素被加入水中时，它会逐渐在液体中扩散。这种现象是由于染料分子的“扩散性”，它们从浓度较高的区域移动到浓度较低的区域。在生物系统中，“扩散性”在呼吸和营养吸收等过程中起着重要作用。例如，氧气和二氧化碳通过一种称为被动运输的过程扩散穿过细胞膜。扩散速率取决于多个因素，包括温度、浓度梯度和参与的分子大小。因此，理解气体的“扩散性”对于研究呼吸生理学至关重要。此外，“扩散性”的概念不仅限于自然科学。在社会科学中，我们可以将物质的扩散与思想或创新在社会中的传播进行类比。正如分子在介质中扩散一样，思想也可以渗透到社区中，影响行为和实践。这一类比强调了“扩散性”的重要性，不仅在物理意义上，而且在隐喻的背景下。为了进一步说明这一点，可以考虑技术的扩散。当一种新设备被引入时，其采用通常遵循类似于“扩散性”的模式。早期采用者就像最初开始在介质中扩散的分子，而大多数用户则在技术变得更易获取且其好处显而易见时跟随。这种模式可以使用“扩散性”的模型进行分析，帮助预测一种新创新被公众接受的速度和广度。总之，“扩散性”是一个多层面的概念，连接着多个学科。无论我们是在讨论溶液中粒子的运动、生物系统中气体的交换，还是社会中信息的传播，“扩散性”原理始终相关。通过理解这一概念，我们可以深入了解物理世界和人类互动的动态。随着我们继续探索“扩散性”的影响，我们可以更好地欣赏所有事物之间的相互联系，从微观到社会层面。