Samples of electrodes with an active layer based on TiO 2 , RuO 2 and oxides of rare earth elements Ce, La, Nd, doped with carbon nanoscale, have been obtained. The morphology of oxide electrodes was studied. Their electrochemical behavior in aqueous solutions of sodium chloride and sulfate was studied. The values ??of the current-free potentials, the values ??of the current densities and the potential regions for the release of chlorine and oxygen from aqueous solutions of sodium chloride and sodium sulfate have been determined. The dependences of the volume of released chlorine on the composition of the electrodes are presented.
Kolesnikov V. A., Novikov V. T., Isaev M. K. et al. Study of electrodes with an active layer of a mixture of oxides TiO2, RuO2, SnO2 // Glass and ceramics. 2018.? 4.S. 26? 32.
? Kolesnikov VA, Novikov VT, Isaev MK et al. Investigation of Electrodes with an Active Layer of a Mixture of the Oxides TiO2, RuO2, SnO2 // Glass Ceram. 2018. V. 75. No. 3? 4. P. 148? 153.?
Novikov V.T., Kolesnikov A.V., Isaev M.K., Goncharova L.A. Investigation of oxide electrodes based on TiO2, RuO2 and SnO2 for electroflotation processes // Electroplating and surface treatment. 2018.Vol. 26.? 2.S. 50? 56.
Liu F., Ma L., Li XB, Yan YG Study on the degradation of dye solution using Ti / IrO2-RuO2 electrode // Water Resources and Environment. Proc. of the Intern. Conf. on Water Resources and Environment, 2016. P. 119? 123.
Zhang C., Tang D., Ni X. Scalable synthesis and excellent catalytic effect of hydrangea-like Ru02 mesoporous materials for lithium-02 batteries // Energy Storage Materials. 2016. V. 2. P. 8? 13.
Yarovaya OV, Lemeshev DO, Mostovaya U. L. et al. Obtaining flat ceramic membrane contactors with a catalytically active layer based on Co3O4. Glass and Ceramics. 2016.? 1.S. 20? 23.
? Yarovaya OV, Lemeshev DO, Mostovaya UL et al. Production of Flat Ceramic Membrane Contactors with a Catalytically Active Layer Based on Co3O4 // Glass Ceram. 2016. V. 73. No. 1? 2. P. 19? 21.?
Otogawa R., Shimizu H., Inoue T. et al. Polarization behavior and lifetime of IrO2? Ta2O5? SnO2 / Ti anodes in p-phenolsulfonic acid solutions for tin plating // Journal of Applied Electrochemistry. 2000. V. 30. No. 4.P. 511? 514.
Horv? Th E., Krist? F J., Frost RL et al. Investigation of IrO2 / SnO2 thin film evolution by thermoanalytical and spectroscopic methods // Journal of thermal analysis and calorimetry. 2004. V. 78. No. 2.P. 687? 695.
De Pauli CP, Trasatti S. Electrochemical surface characterization of IrO2 + SnO2 mixed oxide electrocatalysts // Journal of Electroanalytical Chemistry. 1995. V. 396. No. 1? 2. P. 161? 168.
De Pauli CP, Trasatti S. Composite materials for electrocatalysis of O2 evolution: IrO2 + SnO2 in acid solution // Journal of electroanalytical Chemistry. 2002. V. 538. P. 145? 151.
Chen X., Chen G. Stable Ti / RuO2? Sb2O5? SnO2 electrodes for O2 evolution // Electrochimica Acta. 2005. V. 50. No. 20.P. 4155? 4159.
Ribeiro J., De Andrade AR Characterization of RuO2 Ta2O5 Coated Titanium Electrode Microstructure, Morphology, and Electrochemical Investigation // Journal of the Electrochemical Society. 2004. V. 151. No. 10.P. D106? D112.
Du L., Wu J., Hu C. Electrochemical oxidation of Rhodamine B on RuO2? PdO? TiO2 / Ti electrode // Electrochimica Acta. 2012. V. 68. P. 69? 73.
Xu wen X., Zhen C., Fuping L. Advanced treatment of biologically pretreated coking wastewater by electrochemical oxidation using Ti / RuO2-lrO2 electrodes // Chem. Technol. and Biotechnol. 2013. No. 8.P. 1568? 1575.
Deng PC, Wang G., Hu JZ, Tian KW Electrochemical depolymerization of chitosans using the IrO2 electrode with interlayers as anode // Materials Science Forum. 2016. V. 847. P. 281? 286.
Hernandez-Mejia C., Gnanakumar ES, Olivos-Suarez A., Gascon J. Ru / TiO2-catalysed hydrogenation of xylose: The role of the crystal structure of the support // Catalysis Science and Technology. 2016. V. 6. P. 577? 582.
Cherevko S., Geiger S., Kasian O. et al. Oxygen and hydrogen evolution reactions on Ru, RuO2, Ir, and IrO2 thin film electrodes in acidic and alkaline electrolytes: A comparative study on activity and stability // Catalysis Today. 2016. V. 262. P. 170? 180.
Liberman E. Yu., Mikhailichenko A. I., Malysheva T. N. et al. Obtaining and thermal stability of nanodispersed bicomponent materials SnO2? CeO2 // Glass and ceramics. 2017.? 9, p. 18? 21.
? Liberman E. Yu., Mikhailichenko AI, Malysheva TN et al. Preparation and Thermal Stability of Nanodisperse Bicomponent Materials in the System SnO2? CeO2 // Glass Ceram. 2017. V. 74. No. nine ? 10.P. 319? 322.?
Tolstov A.V., Pokhilenko N.P., Samsonov N. Yu. New possibilities for obtaining rare earth elements from a single Arctic source of raw materials // Journal of the Siberian Federal University. Chemistry. 2017.? 10 (1). C. 125? 138.
Audichon T., Morisset S., Napporn TW et al. Effect of Adding CeO2 to RuO2? IrO2 Mixed Nanocatalysts: Activity towards the Oxygen Evolution Reaction and Stability in Acidic Media // ChemElectroChem. 2015. V. 2. No. 8.P. 1128? 1137.
Lee DG, Kim B.-H. MnO2 decorated on electrospun carbon nanofiber / graphene composites as supercapacitor electrode materials // Synthetic Metals. 2016. V. 219. P. 115? 123.
Hsu D Y.-H., Lai C.-C., Ho C.-L., Lo C.-T. Preparation of interconnected carbon nanofibers as electrodes for supercapacitors // Electrochimica Acta. 2014. V. 127. P. 369? 376.
Ojha D GP, Pant B., Park S.-J. et al. Synthesis and characterization of reduced graphene oxide decorated with CeO2-doped MnO2 nanorods for supercapacitor
applications // Journal of Colloid and Interface Science. 2017. V. 494. P. 338? 344.
The article can be purchased
electronic!
PDF format
700 руб
UDK 666.7:544.6:546.82
Article type:
Not-set
Make a request
