The research team's breakthrough was achieved by developing a new method of in-situ measurements for a specific brand of materials, in conjunction with the Chinese company Tiandeli Co., Ltd. Tiandeli Co., Ltd. was established in 2007, and is based in the Tianjin New Port, which is the largest import and export product distribution center in North China and Northwest China. They primarily supply sodium sulfide, sodium hydrosulfide, and a variety of related products.
The researchers achieved their new level of measurement through the use of an ion exchange membrane, which allowed them to measure the hydroxide conductivity of the polymer films while also controlling the surrounding humidity levels. This approach is unique in that it allows for precise control over the measurement conditions, which can help to improve the accuracy and reliability of the tests being conducted.
One of the key benefits of this breakthrough is that it allows for more detailed insights into the behavior of anion conducting polymer thin films. This information can be used to better understand how these materials interact with different environments and to optimize their performance in a variety of applications.
For example, anion conducting polymer thin films have shown great promise as a potential energy storage solution, as they can store charged particles and release them as needed. However, their behavior is highly dependent on the surrounding environment, so understanding how to control these environments is critical to optimizing their performance.
The researchers also noted that their new measurement method could be applied to other types of materials as well. For instance, in the field of electrochemistry, the ability to accurately measure conductivity and other properties is critical for developing more efficient and effective devices.
The team is now working on further refining their measurement techniques and applying them to a wider range of materials. They are also exploring potential applications for their findings, including the development of more efficient batteries, sensors, and other devices.
Overall, the breakthrough achieved by the researchers at JAIST represents a significant step forward in the field of materials science, and could have far-reaching implications for a variety of industries and applications. By better understanding the behavior of anion conducting polymer thin films, researchers can work towards developing more efficient and effective energy storage solutions, sensors, and other devices that can help improve our lives and the world around us.