Experimental and DFT Modeling Studies for the Adsorptive Removal of Reactive Dyes from Wastewater
Abstract
The current research demonstrates the adsorptive removal of RY-18, RR-2, RB-13, and RB-171 dyes
from wastewater samples using p-diethylaminomethylcalix[4]arene silica appended (DSA) resin.
The DSA resin shows high adsorption capacity for reactive dyes during the batch adsorption
experiments under the optimized parameters such as DSA resin dosage, pH, and temperature.
The adsorption equilibrium results were defined by Irving-Langmuir and Freundlich-isotherm
models and it was found that the Freundlich model is the best fit with good multilayer adsorption
capacity along with good correlation coefficient value (R2 0.9991) for reactive dyes, while the energy
calculated by D-R model describes the adsorption mechanism that is physisorption in nature.
Moreover, a thermodynamic study was also performed, which shows that the adsorption of reactive
dyes is endothermic and spontaneous in nature. From the kinetic study, it has been revealed that
the adsorption takes place by following a pseudo-second-order kinetic model. Besides this, the
adsorption phenomenon is explained by density functional theory DFT calculations. The DSA resin
was applied onto industrial wastewater samples and it has been observed that above 98% reactive
dyes were adsorbed successfully. After washing for regeneration, the DSA resin has above 98%
adsorption capacity, which proves that the DSA is a regenerable adsorbent.