Kinetics of Water Vapor Adsorption on Single-Layer Molecular Sieve 3A: Experiments and Modeling
Citations Over TimeTop 20% of 2014 papers
Abstract
The objective of the current work was to shorten the gap for fundamental adsorption kinetic data required for the development of advanced adsorption unit-operation models to be incorporated into an overall plant-level model for spent nuclear fuel reprocessing. The kinetics of water-vapor adsorption on molecular sieve 3A was investigated at 25–80 °C and water dew points from −69 to 17 °C. Water uptake curves were fitted with three kinetic models including the linear-driving-force model, the shrinking-core model, and the Langmuir kinetic model. The results suggest that the water-vapor adsorption on molecular sieve 3A under the investigated experimental conditions was controlled by both external film resistance and internal macropore resistance. The contribution of the external film resistance varied from 25% to 50% of the total mass-transfer resistance depending on the adsorption temperature. It was also found that the Langmuir kinetic model fitted individual sets of kinetic data very well, but the Langmuir adsorption constant obtained from curve fitting decreased with increasing adsorption temperature and with increasing water vapor pressure. This result indicates a significant surface heterogeneity of molecular sieve 3A and also implicitly verifies that the Langmuir isotherm model is unable to represent isotherms of water adsorption on molecular sieve 3A.
Related Papers
- → Can the Langmuir adsorption coefficient be used to derive the adsorption Gibbs energy?(2022)22 cited
- → Adsorption of water from methanol solution using various adsorbent(2017)4 cited
- Adsorption kinetics of Cr(VI) in sewage on mesoporous molecular sieve MCM-41.(2010)
- ADSORBENT EFFECT AND APPLICABILITY OF LANGMUIR EQUATION FOR DESCRIBING ION ADSORPTION IN LIQUID/SOLID SYSTEMS(2007)
- → Construction and experimental study of Langmuir model for multi-molecular layer adsorption of porous materials(2021)1 cited