Artificial intelligence-based neural network modeling of adsorptive removal of phenol from aquatic environment

In this study, adsorptive uptake of phenol from aqueous system using Arachis hypogaea (groundnut) shell-based adsorbent was experimentally investigated and modelled using artificial intelligence-based neural network approach. Artificial neural networks with different number of neurons were designed using Levenberg-Marquardt algorithm to find the best model for phenol adsorption. The feedforward back propagation neural network comprising TRAINLM, LARNGDM and TANSIG as training, adaptation learning and transfer functions, respectively, with ten neurons in the hidden layer exhibited the optimal architecture with the strongest correlation (R = 0.9901) 2 and the smallest mean square error ( MSE= 0.045). The studies indicated a maximum adsorptive uptake of phenol to be 37.31 mg/g onto the activated shell powder. The kinetic analysis favored pseudo second order =R( 0.9999) 2 and the equilibrium data was best represented by Freundlich isotherm model (R = 0.9976) 2 . Phenolic remediation phenomenon ensued in a spontaneous manner, was exothermic ( H = 34.25kJ/mol) 0 and involved physisorption. The experimental results are agreement with model.