Almalawi, A. and Khan, A.I. and Alqurashi, F. and Abushark, Y.B. and Alam, M.M. and Qaiyum, S. (2022) Modeling of Remora Optimization with Deep Learning Enabled Heavy Metal Sorption Efficiency Prediction onto Biochar. Chemosphere, 303.
Full text not available from this repository.Abstract
Environmental distresses linked to heavy metal (HM) impurity in the water received significant attention among research communities. Recently, advancements in industrial sectors like paper industries, mining, non-ferrous metallurgy, electroplating, mineral paint production, etc. have resulted in massive heavy metals in wastewater. In contrast to organic pollutants, HMs are not recyclable and can be simply engrossed by living organisms. Recently, different solutions have been employed for removing HMs from water and wastewater, like membrane filtration, chemical precipitation, adsorption, ion-exchange, flotation, flocculation, etc. Sorption can be considered one of the efficient solutions for eradicating HMs from waste water. With this motivation, this article concentrates on the design of Remora Optimization with Deep Learning Enabled Heavy Metal Sorption Efficiency Prediction (RODL-HMSEP) model onto Biochar. The proposed RODL-HMSEP technique intends to determine the sorption performance of HMs of various biochar features. Initially, the density based clustering (DBSCAN) technique is applied to simulating the features of metal adsorption data and splitting them into clusters of identical features. Besides, deep belief network (DBN) model was employed for prediction and the efficiency of the DBN model is optimally adjusted with utilize of RO technique. The experimental validation of the RODL-HMSEP technique ensured the promising performance of the RODL-HMSEP technique on the prediction of sorption efficiency onto biochar over other methods The experimental validation of the RODL-HMSEP technique ensured the promising performance of the RODL-HMSEP technique on the prediction of sorption efficiency onto biochar over other methods. © 2022 Elsevier Ltd
Item Type: | Article |
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Impact Factor: | cited By 0 |
Uncontrolled Keywords: | Biology; Deep learning; Efficiency; Flotation; Forecasting; Ion exchange; Microfiltration; Precipitation (chemical); Sorption, Biochar; Deep learning; Efficiency predictions; Metal sorption; Optimisations; Optimization algorithms; Prediction techniques; Predictive models; Remora optimization algorithm; Sorption efficiency, Heavy metals, adsorbent; charcoal; heavy metal; mineral; paint; water; charcoal; heavy metal, adsorption; biochar; heavy metal; membrane; sorption; waste, adsorption; algorithm; Article; artificial neural network; clustering algorithm; data clustering; deep belief network; deep learning; electroplating; flocculation; flotation; ion exchange; mathematical model; metallurgy; paper mill; precipitation; predictive model; probability; process optimization; restricted Boltzmann machine; waste water management; wastewater; chemistry; water pollutant, Biology; Efficiency; Flotation; Forecasts; Ion Exchange; Sorption, Adsorption; Charcoal; Deep Learning; Metals, Heavy; Waste Water; Water Pollutants, Chemical |
Depositing User: | Ms Sharifah Fahimah Saiyed Yeop |
Date Deposited: | 26 Jul 2022 06:40 |
Last Modified: | 26 Jul 2022 06:40 |
URI: | http://scholars.utp.edu.my/id/eprint/33326 |