Experimental and theoretical investigation of water sorption on lemon leaves: New perspectives with statistical physical modeling.

[Display omitted] • New statistical physical insights of the water sorption isotherms on lemon leaves; • A finite multilayer model represented the isotherms at 40, 50, and 60 °C; • The experimental sorption isotherms obtained for lemon leaves are Type II; • Sorption energies are less than 50 kJ mol−1. A deeper analysis of the water sorption isotherms on lemon leaves (40, 50, and 60 °C) was carried out using statistical physical modeling to obtain information about the sorption mechanism and better understand the process. For this, a theoretical model was developed based on the grand canonical potential to describe the experimental data, and the isotherms were analyzed using the finite multilayer sorption model. The experimental sorption isotherms obtained for lemon leaves are Type II. The model used to analyze the process showed excellent predictive capacity, with coefficient of determination values above 0.97 and root mean square error below 0.08. The interpretation of the estimated parameters indicated that the water molecules are parallel to the surface of the lemon leaves, which allows the formation of finite layers of water. The system is directly affected by temperature, where increasing temperature decreases the density of receptor sites. The process occurs through physisorption since the calculated sorption energies are less than 50 kJ mol−1. The thermodynamic analysis of the process shows that water sorption on leaves is exothermic and spontaneous. This work contributes to a better understanding the drying process through the results obtained. [ABSTRACT FROM AUTHOR]