Improving the Treatment Efficiency and Lowering the Operating Costs of Electrochemical Advanced Oxidation Processes

Muddemann, Thorben; Neuber, Rieke; Haupt, Dennis; Graßl, Tobias; Issa, Mohammad; Bienen, Fabian; Enstrup, Marius; Möller, Jonatan; Matthée, T.; Sievers, Michael; Kunz, Ulrich

doi:10.3390/pr9091482

Cited by 16 publications

(7 citation statements)

References 49 publications

(66 reference statements)

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“…In the study by Santos et al, 20 the same efficiency was reached (99.9%), but in the presence of 20 g l −1 NaCl and EC was 7.33 kWh kg phenol −1 . Similar result was achieved in a study by Muddemann et al 4 where EC was 103.02 kWh kg −1 with almost complete mineralization (>99% COD), using BDD anode and SS cathode, but with 9 g l −1 Na 2 SO 4 . Some studies have shown very high energy consumption as, for example, in the case of treatment of phenolic wastewaters from cashew-nut processing industry with BDD anode by applying 20 mA cm −2 .…”

Section: Resultssupporting

confidence: 89%

“…Similarly, Oliveira et al 19 showed high efficiency of Ti/RuO 2 -TiO 2 anode. However, BDD anode might have other advantages such as lifespan of up to 18 years, significantly reducing the cost of EO, as claimed by Muddemann et al 4 Energy consumption.-The lowest energy consumption (EC) was recorded in electrolyte NaCl, and was 116.6 kWh kg phenol −1 at E f 99.9% (Fig. 4).…”

Section: Resultsmentioning

confidence: 86%

“…Electrochemical oxidation (EO) is important as one of the more eco-friendy AOPs. 4,5 EO is used for removal of pollutants from wastewaters because of its significant advantages: it is based on the in situ production of the hydroxyl radical. 6 The most important parameter affecting mechanism of EO is the anode material [7][8][9] which can be active (i.e.…”

mentioning

confidence: 99%

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Electrooxidation of Phenol on Boron-doped Diamond and Mixed-metal Oxide Anodes: Process Evaluation, Transformation By-products, and Ecotoxicity

Đuričić

Prosen

Kravos

et al. 2023

J. Electrochem. Soc.

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Phenolic pollutants raise health and environmental concerns due to their widespread occurrence in industrial wastewaters. Electrooxidation was studied for phenol degradation in different supporting electrolytes: NaCl, Na2SO4, H2SO4. Experiments were performed at constant current density 20 mA/cm2. Two anode materials were tested, boron-doped diamond (BDD) and mixed-metal oxide (MMO). Degradation process and its impact was investigated from technological, analytical, and ecotoxicological viewpoints. Removal efficiency was monitored by phenol index spectrophotometric method and phenol removal quantified with HPLC-DAD. Additionally, transformation by-products were tracked with GC-MS and LC-MS, as well as ion chromatography. Finally, ecotoxicity was investigated using Daphnia magna. Electrooxidation was efficient and had low energy consumption. The use of BDD anode led to higher removal efficiencies and induced more progressive degradation to simple organic acids, compared to MMO. Selection of electrolyte affected degradation pathways and detoxification pattern. Treatment by BDD in NaCl led to complete phenol removal in 30 min, but undesired chlorinated aromatic by-products were formed. Treatment in sulphate medium led to slower processes irrespective of pH, but less problematic by-products with minimal ecotoxicological impact emerged. By using multi-aspect methodology, this study reevaluates phenol electrooxidative degradation and contributes to better understanding of electrooxidation performance in water treatment.

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Section: Resultssupporting

confidence: 89%

Section: Resultsmentioning

confidence: 86%

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Electrooxidation of Phenol on Boron-doped Diamond and Mixed-metal Oxide Anodes: Process Evaluation, Transformation By-products, and Ecotoxicity

Đuričić

Prosen

Kravos

et al. 2023

J. Electrochem. Soc.

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“…BCRs are one of the most applied gas-liquid and gas-liquid-solid multiphase reactors in industrial processes. They are characterized by many benefits such as easy operation, efficient mixing, high heat and mass-transfer rates, low maintenance costs, and low energy consumption [11][12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Combining α-Al2O3 Packing Material and a ZnO Nanocatalyst in an Ozonized Bubble Column Reactor to Increase the Phenol Degradation from Wastewater

Majhool,

Sukkar,

Alsaffar

2023

Processes

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The ozonation reaction in a bubble column reactor (BCR) has been widely used in the removal of phenol from wastewater, but the phenol removal efficiency in this type of reactor is limited because of low ozone solubility and reactivity in the system. In the present study, the phenol degradation in the BCR was enhanced by using α-Al2O3 as a packing material and a ZnO nanocatalyst. The reactor diameter and height were 8 cm and 180 cm, respectively. The gas distributor was designed to include 52 holes of a 0.5 mm diameter. Also, the gas holdup, pressure drop, and bubble size were measured as a function of the superficial gas velocity (i.e., 0.5, 1, 1.5, 2, 2.5, and 3 cm/s). The evaluation of the hydrodynamic parameters provided a deeper understanding of the ozonation process through which to select the optimal operating parameters in the reactor. It was found that the best superficial gas velocity was 2.5 cm/s. A complete (100%) phenol removal was achieved for phenol concentrations of 15, 20, and 25 ppm at reaction times of 80, 90, and 100 min, respectively; this was achieved by using α-Al2O3 packing material and a ZnO nanocatalyst in the BCR. Additionally, a reaction kinetics study was conducted to describe the ozonation reaction in BCR. The first-order reaction assumption clearly describes the reaction kinetics with an R2 = 0.991. Finally, the applied treatment method can be used to efficiently remove phenol from wastewater at a low cost, with a small consumption of energy and a simple operation.

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“…When the OEP of the anode is lower than the direct electron transfer potential of organic pollutants, the oxygen evolution reaction occurs first in the anode during the electrolysis (Rodriguez-Narvaez et al 2021). This reduces the rate of • OH generated and the current efficiency, and prolongs the electrolysis duration, resulting in higher energy consumption (Muddemann et al 2021). Therefore, the choice of anode material is extremely critical.…”

Section: Introductionmentioning

confidence: 99%

PbO2 modified BDD electrode by dicationic ionic liquids assisted electrodeposition for efficient electrocatalytic degradation of pesticide wastewater

Tang

Feng

2022

Water Science and Technology

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Pesticide wastewater is difficult to treat, and it is necessary to develop a new anode material electrochemical oxidation to efficiently degrade pesticide wastewater. DIL-PbO2-Ti/BDD electrodes with better electrocatalytic oxidation performance were obtained by using dicationic ionic liquid (DIL) for assisted electrodeposition of PbO2 modified boron-doped diamond (BDD) electrodes. At a current density of 100 mA cm−2 and a temperature of 25 °C using the DIL-PbO2-Ti/BDD electrode as anode and titanium plate as cathode. The electrochemical window and Oxygen evolution potential (OEP) of the DIL-PbO2-Ti/BDD electrode obtained by CV testing at a scan rate of 50 mV s−1 in 1 M H2SO4 were 4.12 V and 3.29 V, respectively. Under the conditions of current density of 100 mA cm−2, 25 °C, pH 12, salt content of 8%, chemical oxygen demand (COD) of 24,280.98 mg L−1, and total nitrogen (TN) content of 5,268 mg L−1, after electrification for 12 h, the removal efficiency of COD and TN reached 64.88% and 67.77%, respectively, indicating that the DIL-PbO2-Ti/BDD electrode has excellent electrocatalytic performance. In order to further understand the mechanism of electrochemical degradation of pesticide wastewater, HPLC-MS was used to detect the intermediates in the degradation process, and the possible degradation pathways were proposed in turn.

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Improving the Treatment Efficiency and Lowering the Operating Costs of Electrochemical Advanced Oxidation Processes

Cited by 16 publications

References 49 publications

Electrooxidation of Phenol on Boron-doped Diamond and Mixed-metal Oxide Anodes: Process Evaluation, Transformation By-products, and Ecotoxicity

Electrooxidation of Phenol on Boron-doped Diamond and Mixed-metal Oxide Anodes: Process Evaluation, Transformation By-products, and Ecotoxicity

Combining α-Al2O3 Packing Material and a ZnO Nanocatalyst in an Ozonized Bubble Column Reactor to Increase the Phenol Degradation from Wastewater

PbO2 modified BDD electrode by dicationic ionic liquids assisted electrodeposition for efficient electrocatalytic degradation of pesticide wastewater

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