Phenol removal from wastewater by CWPO process over the Cu-MOF nanocatalyst: process modeling by response surface methodology (RSM) and kinetic and isothermal studies
New Journal of Chemistry Pub Date: 2020-12-28 DOI: 10.1039/D0NJ04128A
Abstract
Water-stable metal–organic frameworks (MOFs), which possess unique porous structures, have attracted attention from scientists exploring novel and efficient methods for the elimination of phenol compounds from aqueous media. The numerous properties of MOFs such as tunable porosity, hierarchical structure, immense pore volume, and specific surface area, together with their excellent adsorption and recyclability performances offer new insight compared to traditional catalysts. Herein, Cu-MOF was synthesized and characterized via FTIR, BET, XRD, TEM, and SEM. Results indicated the formation of nanostructured Cu-MOF with mesoporous and macroporous characteristics. Cu-MOF was employed as a new catalyst in the catalytic wet peroxide oxidation (CWPO) of phenol. The central composite design of the RSM (response surface methodology) approach was used for the design of the CWPO process in the statistical study of the removal of phenol from wastewater. The RSM methodology predicted that the optimal conditions for the phenol degradation occured at phenol concentration 400 ppm, Cu-MOF amount (1.5 g L?1) at 50 °C for 30 min. The phenol removal percentage under optimal conditions was predicted by RSM to be 91.4% where experimental test resulted 91.87% removal of phenol. The order of the relative significance of variables predicted by the Pareto analysis was as follows: temperature (X3) > concentration (X1) > adsorbent dosage (X2) > contact time (X4). Furthermore, the isotherms (Langmuir and Freundlich) and kinetics of phenol oxidation in the CWPO process were investigated for the adsorption of phenol on Cu-MOF. The average values of the empirical constant, adsorption constant (saturation coefficient) and R2 for the Langmuir equation were qm = ?500 mg g?1, KL? =? 0.19 L mg and 0.88, respectively. The average values of the Freundlich adsorption constant, empirical coefficient and R2 were Kf? = ?1.44 mg g?1, n? = ?0.66 L mg?1 and 0.94, respectively. The results indicated that the data was better fitted with the Freundlich model. Finally, the kinetics of the process was confirmed to correspond to the pseudo-second-order equation.
Recommended Literature
- [1] Dissociative electron attachment to HGaF4 Lewis–Br?nsted superacid Marcin Czapla,Jack SimonsPhys. Chem. Chem. Phys., 2018,20, 21739-21745 10.1039/C8CP04007A
- [2] Enabling stable MnO2 matrix for aqueous zinc-ion battery cathodes? Yiding Jiao,Liqun Kang,Jasper Berry-Gair,Kit McColl,Jianwei Li,Haobo Dong,Hao Jiang,Ryan Wang,Furio Corà,Dan J. L. Brett,Ivan P. ParkinJ. Mater. Chem. A, 2020,8, 22075-22082 10.1039/D0TA08638J
- [3] Empowering microfluidics by micro-3D printing and solution-based mineral coating? Hongxia Li,Aikifa Raza,Qiaoyu Ge,Jin-You Lu,TieJun ZhangSoft Matter, 2020,16, 6841-6849 10.1039/D0SM00958J
- [4] Fe3O4 nanoclusters highly dispersed on a porous graphene support as an additive for improving the hydrogen storage properties of LiBH4? Guang Xu,Wei Zhang,Ying Zhang,Xiaoxia Zhao,Ping Wen,Di MaRSC Adv., 2018,8, 19353-19361 10.1039/C8RA02762E
- [5] Excellent energy storage performance in NaNbO3-based relaxor antiferroeic ceramics under a low electric field XuxinCheng,XiaomingChen,PengyuanFan 10.1007/s10832-022-00283-w
- [6] EWOD-driven droplet microfluidic device integrated with optoelectronic tweezers as an automated platform for cellular isolation and analysis? Gaurav J. Shah,Eric P.-Y. Chiou,Ming C. Wu,Chang-Jin “CJ” KimLab Chip, 2009,9, 1732-1739 10.1039/B821508A
- [7] Emerging investigator series: bacteriophages as nano engineering tools for quality monitoring and pathogen detection in water and wastewater Fereshteh BayatEnviron. Sci.: Nano, 2021,8, 367-389 10.1039/D0EN00962H
- [8] Emerging investigator series: first-principles and thermodynamics comparison of compositionally-tuned delafossites: cation release from the (001) surface of complex metal oxides? Joseph W. Bennett,Diamond T. Jones,Blake G. Hudson,Joshua Melendez-Rivera,Robert J. Hamers,Sara E. MasonEnviron. Sci.: Nano, 2020,7, 1642-1651 10.1039/C9EN01304K
- [9] Evidence of rutile-to-anatase photo-induced electron transfer in mixed-phase TiO2 by solid-state NMR spectroscopy? Weili Dai,Guangjun Wu,Michael HungerChem. Commun., 2015,51, 13779-13782 10.1039/C5CC04971G
- [10] Excellent peroxidase mimicking property of CuO/Pt nanocomposites and their application as an ascorbic acid sensor? Xinhuan Wang,Shuangfei Cai,Cui QiAnalyst, 2017,142, 2500-2506 10.1039/C7AN00589J
Journal Name:New Journal of Chemistry
research_products
-
CAS no.: 89640-58-4
![1,2,3,4,5,6-Hexahydro-[2,3]bipyridinyl-6-ol](https://ossimg.kuujia.com/scimg/1271000/1270529-38-8x500.png)
![N-(3-cyanothiolan-3-yl)-2-[(2,2,2-trifluoroethyl)sulfanyl]pyridine-4-carboxamide](https://ossimg.kuujia.com/scimg/1444500/1444113-98-7x500.png)
![2,2-Difluoro-3-[methyl(2-methylbutyl)amino]propanoic acid](https://ossimg.kuujia.com/scimg/2138500/2138166-62-6x500.png)
![2-(1H-indol-3-yl)-N-{[6-(thiophen-2-yl)-[1,2,4]triazolo[4,3-b]pyridazin-3-yl]methyl}acetamide](https://ossimg.kuujia.com/scimg/2034500/2034271-14-0x500.png)