ionic conductance

简明释义

离子电导性

英英释义

例句

1.Researchers measured the ionic conductance of various electrolytes to find the most efficient one.

研究人员测量了各种电解质的离子导电性以找到最有效的。

2.The study of ionic conductance helps us understand how ions move through solutions.

对离子导电性的研究帮助我们理解离子如何在溶液中移动。

3.In batteries, ionic conductance is crucial for the flow of current.

在电池中，离子导电性对于电流的流动至关重要。

4.High ionic conductance in a solution indicates a greater concentration of ions.

溶液中的高离子导电性表明离子的浓度更高。

5.The ionic conductance of the membrane was tested to evaluate its performance in ion transport.

膜的离子导电性被测试以评估其在离子运输中的性能。

作文

Ionic conductance is a crucial concept in the field of electrochemistry and materials science. It refers to the ability of ions to move through a medium, which can be either a liquid or solid. This movement of ions is essential for various processes, including the functioning of batteries, fuel cells, and even biological systems such as nerve impulses and muscle contractions. Understanding ionic conductance (离子导电性) allows scientists and engineers to design better materials and devices that can efficiently conduct electric current. In batteries, for instance, ionic conductance (离子导电性) plays a significant role in determining how quickly a battery can charge and discharge. A battery with high ionic conductance (离子导电性) will allow ions to move freely between the anode and cathode, resulting in faster energy transfer. This is particularly important in applications where quick charging is required, such as in electric vehicles and portable electronics. Moreover, the study of ionic conductance (离子导电性) extends beyond just batteries. In fuel cells, which convert chemical energy directly into electrical energy, the efficiency of the cell is heavily influenced by the ionic conductance (离子导电性) of the electrolyte material used. A higher ionic conductance (离子导电性) means that the fuel cell can operate more effectively, leading to better performance and lower costs. In biological systems, ionic conductance (离子导电性) is vital for the transmission of signals in the nervous system. Neurons communicate with each other through action potentials, which are generated by the movement of ions across the cell membrane. The ability of these ions to conduct electricity is what allows for rapid communication within the body. Understanding the mechanisms behind ionic conductance (离子导电性) in biological systems can lead to advancements in medical science, particularly in treating neurological disorders. The measurement of ionic conductance (离子导电性) is typically performed using techniques such as impedance spectroscopy, which allows researchers to analyze how ions move through different materials. This information can be used to improve existing technologies or develop new ones. For example, researchers are constantly looking for new materials with enhanced ionic conductance (离子导电性) properties that could revolutionize the energy storage industry. In conclusion, ionic conductance (离子导电性) is a fundamental property that influences a wide range of scientific and engineering disciplines. From improving battery technology to understanding biological processes, the implications of ionic conductance (离子导电性) are vast and significant. As research continues to advance, we can expect to see even more innovative applications that harness the power of ionic conductance (离子导电性).

离子导电性是电化学和材料科学领域的一个重要概念。它指的是离子在介质中移动的能力，这可以是液体或固体。这种离子的运动对于各种过程至关重要，包括电池、燃料电池的功能，甚至生物系统，如神经冲动和肌肉收缩。理解离子导电性（ionic conductance）使科学家和工程师能够设计出更好的材料和设备，从而有效地导电。例如，在电池中，离子导电性（ionic conductance）在决定电池充电和放电速度方面起着重要作用。具有高离子导电性（ionic conductance）的电池将允许离子在阳极和阴极之间自由移动，从而实现更快的能量传输。这在需要快速充电的应用中尤为重要，例如电动车和便携式电子设备。此外，离子导电性（ionic conductance）的研究不仅限于电池。在燃料电池中，它将化学能直接转化为电能，电池的效率受到所用电解质材料的离子导电性（ionic conductance）的严重影响。更高的离子导电性（ionic conductance）意味着燃料电池可以更有效地运行，从而提高性能并降低成本。在生物系统中，离子导电性（ionic conductance）对神经系统信号的传递至关重要。神经元通过动作电位与彼此通信，动作电位是由离子穿过细胞膜的运动产生的。这些离子导电的能力使得身体内的快速交流成为可能。理解生物系统中离子导电性（ionic conductance）背后的机制可以推动医学科学的发展，尤其是在治疗神经系统疾病方面。离子导电性（ionic conductance）的测量通常使用阻抗谱技术进行，这使研究人员能够分析离子如何在不同材料中移动。这些信息可以用于改善现有技术或开发新技术。例如，研究人员不断寻找具有增强离子导电性（ionic conductance）特性的材料，这可能会彻底改变能源存储行业。总之，离子导电性（ionic conductance）是一种基本属性，影响着广泛的科学和工程学科。从改善电池技术到理解生物过程，离子导电性（ionic conductance）的影响是广泛而重要的。随着研究的持续推进，我们可以期待看到更多创新应用，利用离子导电性（ionic conductance）的力量。