Development of a differential photoacoustic system for the determination of the effective water diffusion and water vapor permeability coefficients in thin films

This paper focused on developing a methodology and metrology using a differential photoacoustic (PA) system to determine the effective water vapor diffusion coefficient [Formula: see text] and the effective permeability coefficient [Formula: see text] in thin films as a piece of paper and standard polystyrene for a controlled relative humidity. The methodology proposes a new differential photoacoustic system, including the water reservoir, relative humidity, and temperature detectors. Two cells, reference/sample, were used to obtain the instrumental function to reduce the electronic and environmental noises. A method based on the study of [Formula: see text] and the behaviors of R 2 as a function of the number of data was proposed to assess the region in which the photoacoustic signal should be processed to determine each effective coefficient. S is the amplitude of the PA signal, [Formula: see text] is the initial amplitude value, [Formula: see text] is the change, t (time), and [Formula: see text] is the water vapor diffusion time. The effective water diffusion coefficient [Formula: see text] for water and polystyrene was 1.90 × 10 −11 m 2 /s and 3.09 × 10 −11 m 2 /s, respectively. The permeability coefficient value for the piece of paper was 4.18 × 10 −9 mol kg −1 cm −2 s −1 Pa −1 , while for polystyrene, it was 6.80 × 10 −9 mol kg −1 cm −2 s −1 Pa −1 for 70% of relative humidity. This methodology can be extended by changing the moisture content on the chamber to obtain the dependence of [Formula: see text] as a function of relative humidity.