Effect of Textural Properties on the Degradation of Bisphenol from Industrial Wastewater Effluent in a Photocatalytic Reactor: A Modeling Approach

Alsaffar, May Ali; Ghany, Mohamed Abdel Rahman Abdel; Mageed, Alyaa K.; AbdulRazak, Adnan A.; Ali, Jamal M.; Sukkar, Khalid A.; Ayodele, Bamidele Victor

doi:10.3390/app13158966

Cited by 5 publications

(3 citation statements)

References 59 publications

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“…According to the results, the neural network model is more accurate than the response surface method. The MLP model has also been used to predict the degradation activity of TiO 2 in degrading Bisphenol A [111]. At present, many models, such as the support vector machine, multilayered feed-forward network, generalized additive model, convolutional neural network, adaptive neuro-fuzzy inference system, big data analysis, and deep learning models, have been used to predict the photocatalytic performance of photocatalysts [112][113][114][115][116][117][118][119].…”

Section: The Intelligent Algorithm Optimally Calculates the Degradati...mentioning

confidence: 99%

Intelligent Algorithms Enable Photocatalyst Design and Performance Prediction

Wang,

Mo,

et al. 2024

Catalysts

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Photocatalysts have made great contributions to the degradation of pollutants to achieve environmental purification. The traditional method of developing new photocatalysts is to design and perform a large number of experiments to continuously try to obtain efficient photocatalysts that can degrade pollutants, which is time-consuming, costly, and does not necessarily achieve the best performance of the photocatalyst. The rapid development of photocatalysis has been accelerated by the rapid development of artificial intelligence. Intelligent algorithms can be utilized to design photocatalysts and predict photocatalytic performance, resulting in a reduction in development time and the cost of new catalysts. In this paper, the intelligent algorithms for photocatalyst design and photocatalytic performance prediction are reviewed, especially the artificial neural network model and the model optimized by an intelligent algorithm. A detailed discussion is given on the advantages and disadvantages of the neural network model, as well as its application in photocatalysis optimized by intelligent algorithms. The use of intelligent algorithms in photocatalysis is challenging and long term due to the lack of suitable neural network models for predicting the photocatalytic performance of photocatalysts. The prediction of photocatalytic performance of photocatalysts can be aided by the combination of various intelligent optimization algorithms and neural network models, but it is only useful in the early stages. Intelligent algorithms can be used to design photocatalysts and predict their photocatalytic performance, which is a promising technology.

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Section: The Intelligent Algorithm Optimally Calculates the Degradati...mentioning

confidence: 99%

Intelligent Algorithms Enable Photocatalyst Design and Performance Prediction

Wang,

Mo,

et al. 2024

Catalysts

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“…Therefore, it was decided to apply an ozone concentration of 20 ppm for all of the following experimental runs. Mukherjee et al [16] and John et al [23] have pointed out that the limited selectivity of the ozonation reaction and the low solubility of ozone in the liquid phase reduce the utilization capacity of ozone gas in the reaction mixture. Accordingly, the oxidation process in the presence of ozone gas alone could not completely convert phenol to CO2 and H2O.…”

Section: Effect Of the Ozone Concentration On The Phenol Conversionmentioning

confidence: 99%

“…In this process, hydrocarbons are broken down into carbon dioxide and water. However, the ozonation process undergoes limited ozone gas utilization efficiency, and some harmful by-products may be generated during ozonation reactions [19][20][21][22][23][24][25]. This problem can be partially solved using the catalytic ozonation process.…”

Section: Introductionmentioning

confidence: 99%

Integrated Process for High Phenol Removal from Wastewater Employing a ZnO Nanocatalyst in an Ozonation Reaction in a Packed Bubble Column Reactor

Majhool,

Sukkar,

Alsaffar

et al. 2023

ChemEngineering

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The use of an ozonized bubble column reactor (OBCR) in wastewater treatment is advantageous due to its efficient mixing and mass transfer characteristics. Among all high-performance features, the ozonation reaction in a BCR undergoes a low dissolution of O3 in the reactor with a limited reaction rate. In this study, the ozonation reaction of phenol in an OBCR was tested using a ZnO nanocatalyst and alumina balls as packing material. Three concentrations of O3 were evaluated (i.e., 10, 15, and 20 ppm), and 20 ppm was found to be the optimum concentration for phenol degradation. Also, two doses (i.e., 0.05 and 0.1 g/L) of ZnO nanocatalysts were applied in the reaction mixture, with the optimal dose found to be 0.1 g/L. Accordingly, three phenol concentrations were investigated in the OBCR (i.e., 15, 20, and 25 ppm) using four treatment methods (i.e., O3 alone, O3/Al2O3, O3/ZnO nanocatalyst, and O3/Al2O3/ZnO nanocatalyst). At a contact time of 60 min and phenol concentration of 15 ppm, the removal rate was 66.2, 73.1, 74.5, and 86.8% for each treatment method, respectively. The treatment experiment that applied the O3/Al2O3/ZnO nanocatalyst produced the highest phenol conversion into CO2 and H2O in the shortest contact time for all phenol concentrations. Thus, the OBCR employed with a ZnO nanocatalyst plus packing material is a promising technology for the rapid and active removal of phenol because it enhances the number of hydroxyl radicals (•OH) generated, which ultimately increases the oxidation activity in the OBCR. Also, the results showed efficient flow characteristics in the OBCR, with channeling problems averted due to appropriate gas movement resulting from the use of packing materials. Finally, it was found that the ozonation process in an OBCR is an efficient method for phenol conversion with good economic feasibility.

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