2018 年 22 巻 4 号 p. 95-102
We report the development of a new gas permeation measuring device based on the differential-pressure method, using a quadrupole mass spectrometer (QMS) that includes an in-situ calibration system. The device was applied to evaluating the high gas barrier property of clay-polymer nanocomposite films. The developed device has a detection limit in gas transmission rate (GTR) comparable or lower than those of other reported methods, when the difference of the sample area is taken into consideration. The gas barrier property of two clay-polymer nanocomposite films (SN and H2B) for H2, He, and O2 was evaluated using this device. A polyimide film (PI) was also measured for comparison. The GTR of SN film for H2 and He at 31°C was 1.2 and 3.1 cm3 (STP) m−2 day−1 atm−1, respectively, which were less than 1/1000 those of PI. The GTR of H2B was 0.43 cm3 (STP) m−2 day−1 atm−1 for He, which was about 1/10 of the SN film. The GTR of H2B for H2 could not be measured because it was below the detection limit (0.1 cm3 (STP) m−2 day−1 atm−1). Similarly, the GTR of SN and H2B for O2 could not be measured because it was below the detection limit (0.007 cm3 (STP) m−2 day−1 atm−1). The temperature dependence of GTR was also evaluated. The diffusion coefficient and the solubility were calculated from the GTR. From the calculated results, we discussed the relationship between the structure, the type of binder and the gas barrier properties of clay-polymer nanocomposite films.