A Comparison Study on the Removal of Phenol From Aqueous Solution Using Organomodified Bentonite and Commercial Activated Carbon

Leili, Mostafa; Faradmal, Javad; Kosravian, Farzaneh; Heydari, Mahdieh

doi:10.17795/ajehe-2698

Cited by 17 publications

(5 citation statements)

References 30 publications

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“…Finally, Haseena et al [ 43 ] investigated the potential use of bentonite in eliminating ammonia from aqueous solutions. Based on the literature [ 44 ], we speculated that bentonite and zeolite could be used to remove phenols and metals from water, which was verified by the results. As noted above, the composite adsorbent BAZLSC can perform ion exchange and adsorption, since it contains bentonite, zeolite, limestone, shell, cement, and activated carbon [ 45 ].…”

Section: Resultssupporting

confidence: 63%

Pollutant Removal from Synthetic Aqueous Solutions with a Combined Electrochemical Oxidation and Adsorption Method

Mojiri

Ohashi

Ozaki

et al. 2018

IJERPH

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Eliminating organic and inorganic pollutants from water is a worldwide concern. In this study, we applied electrochemical oxidation (EO) and adsorption techniques to eliminate ammonia, phenols, and Mo(VI) from aqueous solutions. We analyzed the first stage (EO) with response surface methodology, where the reaction time (1–3 h), initial contaminant concentration (10–50 mg/L), and pH (3–6) were the three independent factors. Sodium sulfate (as an electrolyte) and Ti/RuO2–IrO2 (as an electrode) were used in the EO system. Based on preliminary experiments, the current and voltage were set to 50 mA and 7 V, respectively. The optimum EO conditions included a reaction time, initial contaminant concentration, and pH of 2.4 h, 27.4 mg/L, and 4.9, respectively. The ammonia, phenols, and Mo elimination efficiencies were 79.4%, 48.0%, and 55.9%, respectively. After treating water under the optimum EO conditions, the solution was transferred to a granular composite adsorbent column containing bentonite, limestone, zeolite, cockleshell, activated carbon, and Portland cement (i.e., BAZLSC), which improved the elimination efficiencies of ammonia, phenols, and molybdenum(VI) to 99.9%. The energy consumption value (8.0 kWh kg−1 N) was detected at the optimum operating conditions.

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Section: Resultssupporting

confidence: 63%

Pollutant Removal from Synthetic Aqueous Solutions with a Combined Electrochemical Oxidation and Adsorption Method

Mojiri

Ohashi

Ozaki

et al. 2018

IJERPH

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“…The result is a reduction of pollutant adsorbed per unit mass of carbon. Mathematically speaking, the term C/(X/M) will decrease with the decrease of M, thus the ADC & AADC will be increased with a reduction of M. Similar trend was found by [6,19,21,[28][29][30] Fig. 7 and Table 1 show that the ADC & AADC is directly proportional with Co. Increase of Co will act on two direction, each of them will increase ADC & AADC.…”

Section: Applicability Of Adsorption Modelssupporting

confidence: 72%

“…A lot of researches had been conducted employing batch adsorption scheme using different adsorbents. The results of these researches indicated that adsorption capacity (ADC) is found to be increased with the increase of pollutant concentration [6,[17][18][19][20][21][22] and with the decrease of carbon dose (CD) [6,17,19]. It is also found that pollutant removal is directly proportional with the adsorbent dose and contact time [16,20,[23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Phenol Removal From Synthetic Wastewater Using Batch Adsorption Scheme

AL-Doury

Alwan

2019

Tikrit j. eng. sci.

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Phenol is one of the most dangerous pollutant of petroleum industry. Thus its removal is very essential. One of the most popular method used to remove phenol is through adsorption by activated carbon. In the present work, batch adsorption experiments are carried out under various operating parameters: pollutant concentration (CO) (10, 30, and 50mg/L), and activated carbon dose (CD) (250-1500mg/1.25L with an increment of 250). All experiments are performed at laboratory temperature (19ºC) and pH of 7 ± 0.1 while a full factorial mode is applied. Many adsorption models are used to fit experimental data and find out adsorption capacity (ADC) which is a widely used term.The results show that phenol can be completely removed and the adsorption capacity depends on the pollutant concentration (CO) and adsorbent dose (CD). The actual adsorption capacity (AADC) is calculated and found to be highly different from adsorption capacity.

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“…On the other hand, The TTB-Mt-1 with the positive charged surfaces could adsorb the pheolics with the negative charge when the pH of solution is higher than pk a . Similar results on the separation of phenolics by sugarcane bagasse (Elayadi et al 2021) and adsorption of phenol by CTB-bentonite (Leili et al 2015) reported the AE of phenolics from OMW was increased when the pH was increased from 2 to 12.…”

Section: Effect Of Phsupporting

confidence: 66%

Preparation of surface modified montmorillonite and its application for adsorption of phenolic compounds from olive mill wastewater

Arabmofrad

Jafari

Lazzara³

et al. 2023

Preprint

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To recover phenolics from olive mill wastewater (OMW), adsorption was performed and compared among raw montmorillonite (Mt) and three modified-Mt forms. The Mt was modified with tetradecyl trimethylammonium bromide (TTB), cetyl trimethylammonium bromide (CTB), and didodecyl dimethylammonium bromide (DDB). The effect of adsorption time, pH and adsorbent concentration on the adsorption efficiency (AE) of phenolics from OMW were investigated. Experimental results revealed that the maximum AE% (93.43%) of TTB-Mt-1 was obtained at pH = 4.7, adsorbent concentration of 0.66 g/L. The Mt and TTB-Mt-1 before and after adsorption in optimum situation were characterized by X-ray diffraction (XRD) and Fourier transform infrared (FT-IR) spectroscopy in order to establish the adsorption behavior-properties relationship. The results show there was successful phenolics adsorption on TTB-Mt-1. The equilibrium data of adsorbed phenolics was fitted well to Langmuir models and the kinetic data indicated that the best fit of experimental data was pseudo-second order model.

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A Comparison Study on the Removal of Phenol From Aqueous Solution Using Organomodified Bentonite and Commercial Activated Carbon

Cited by 17 publications

References 30 publications

Pollutant Removal from Synthetic Aqueous Solutions with a Combined Electrochemical Oxidation and Adsorption Method

Pollutant Removal from Synthetic Aqueous Solutions with a Combined Electrochemical Oxidation and Adsorption Method

Phenol Removal From Synthetic Wastewater Using Batch Adsorption Scheme

Preparation of surface modified montmorillonite and its application for adsorption of phenolic compounds from olive mill wastewater

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