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Journal Abstract Search

347 related items for PubMed ID: 32679632

  • 1. Degradation of thiocyanate by electrochemical oxidation process in coke oven wastewater: Role of operative parameters and mechanistic study.
    Turan A, Keyikoglu R, Kobya M, Khataee A.
    Chemosphere; 2020 Sep; 255():127014. PubMed ID: 32679632
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  • 2. Electrochemical treatments of coking wastewater and coal gasification wastewater with Ti/Ti4O7 and Ti/RuO2-IrO2 anodes.
    Zhi D, Zhang J, Wang J, Luo L, Zhou Y, Zhou Y.
    J Environ Manage; 2020 Jul 01; 265():110571. PubMed ID: 32421562
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  • 3. Persulfate enhanced electrochemical oxidation of highly toxic cyanide-containing organic wastewater using boron-doped diamond anode.
    Yang W, Liu G, Chen Y, Miao D, Wei Q, Li H, Ma L, Zhou K, Liu L, Yu Z.
    Chemosphere; 2020 Aug 01; 252():126499. PubMed ID: 32224356
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  • 4. Performance of (in)active anodic materials for the electrooxidation of phenolic wastewaters from cashew-nut processing industry.
    Oliveira EMS, Silva FR, Morais CCO, Oliveira TMBF, Martínez-Huitle CA, Motheo AJ, Albuquerque CC, Castro SSL.
    Chemosphere; 2018 Jun 01; 201():740-748. PubMed ID: 29547862
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  • 5. Degradation of cyanide, aniline and phenol in pre-treated coke oven wastewater by peroxide assisted electro-oxidation process.
    Singh H, Mishra BK.
    Water Sci Technol; 2018 Dec 01; 78(10):2214-2227. PubMed ID: 30629549
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  • 7. Electrochemical degradation of Mordant Blue 13 azo dye using boron-doped diamond and dimensionally stable anodes: influence of experimental parameters and water matrix.
    Kenova TA, Kornienko GV, Golubtsova OA, Kornienko VL, Maksimov NG.
    Environ Sci Pollut Res Int; 2018 Oct 01; 25(30):30425-30440. PubMed ID: 30159847
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  • 8. Electrochemical Fenton-based treatment of tetracaine in synthetic and urban wastewater using active and non-active anodes.
    Ridruejo C, Centellas F, Cabot PL, Sirés I, Brillas E.
    Water Res; 2018 Jan 01; 128():71-81. PubMed ID: 29091806
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  • 10. Advanced treatment of biologically pretreated coking wastewater by electrochemical oxidation using boron-doped diamond electrodes.
    Zhu X, Ni J, Lai P.
    Water Res; 2009 Sep 01; 43(17):4347-55. PubMed ID: 19595422
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  • 13. Toward efficient electrocatalytic degradation of iohexol using active anodes: A laser-made versus commercial anodes.
    Bomfim SA, Dória AR, Gonzaga IMD, Oliveira RVM, Romão LPC, Salazar-Banda GR, Ferreira LFR, Eguiluz KIB.
    Chemosphere; 2022 Jul 01; 299():134350. PubMed ID: 35331750
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  • 14. Characterization and comparison of Ti/TiO2-NT/SnO2-SbBi, Ti/SnO2-SbBi and BDD anode for the removal of persistent iodinated contrast media (ICM).
    Moura de Salles Pupo M, Albahaca Oliva JM, Barrios Eguiluz KI, Salazar-Banda GR, Radjenovic J.
    Chemosphere; 2020 Aug 01; 253():126701. PubMed ID: 32302902
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  • 15. Maximization of current efficiency for organic pollutants oxidation at BDD, Ti/SnO2-Sb/PbO2, and Ti/SnO2-Sb anodes.
    Xing X, Ni J, Zhu X, Jiang Y, Xia J.
    Chemosphere; 2018 Aug 01; 205():361-368. PubMed ID: 29704843
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  • 16. Role of electrode materials for the anodic oxidation of a real landfill leachate--comparison between Ti-Ru-Sn ternary oxide, PbO(2) and boron-doped diamond anode.
    Panizza M, Martinez-Huitle CA.
    Chemosphere; 2013 Jan 01; 90(4):1455-60. PubMed ID: 23026163
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  • 19. Relationship between anode material, supporting electrolyte and current density during electrochemical degradation of organic compounds in water.
    Guzmán-Duque FL, Palma-Goyes RE, González I, Peñuela G, Torres-Palma RA.
    J Hazard Mater; 2014 Aug 15; 278():221-6. PubMed ID: 24981674
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  • 20. Electrochemical oxidation of aniline using Ti/RuO2-SnO2 and Ti/RuO2-IrO2 as anode.
    Zhu X, Hu W, Feng C, Chen N, Chen H, Kuang P, Deng Y, Ma L.
    Chemosphere; 2021 Apr 15; 269():128734. PubMed ID: 33143899
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