Affiliation:
1. Chelyabinsk State University
Abstract
Electrochemical reduction of hydrogen (hydronium ion) was carried out on zinc, aluminum and copper cathodes from acidic aqueous solutions containing sulfuric acid (0.09, 0.18 and 0.36 mol/l) to study the effect of electrolyte acidity, the type of cathodes used and potential values on electrolysis indicators. The studies were carried out on the potentiostat using a three-electrode cell under conditions of intensive electrolyte stirring with a magnetic stirrer. At the initial stage, electrolysis was performed in the following modes: potentiodynamic measurements at a sweep rate of 1 mV/s in the potential range Е = –(700÷850) mV on a copper and aluminum electrode and Е = –(1000÷1150) mV on a zinc electrode. In the indicated potential range, hydronium discharge parameters at each cathode were calculated: Tafel slope, apparent transfer coefficients and exchange currents. Dependences of these parameters on electrolyte acidity were considered. Average values of steady state potentials were obtained, which, similar to the apparent exchange current, significantly depended on the cathode material: –923.1 mV (zinc cathode); +36.1 mV (copper cathode), and –603.7 mV (aluminum cathode) (AgCl/Ag). The effect of surfactants on all the kinetic parameters considered was shown. The order of the reaction with and without surfactant additives was determined. At the next stage, the electrochemical parameters of hydronium discharge on the copper electrode only were compared. It was shown that the electrochemical parameters significantly depend on the cathodic potential range where they are determined, and on the methods used for their calculation. It was noted that the process proceeds in the region of mixed kinetics. As the electrode polarization decreases, the hydrogen discharge mechanism changes, while the proportion of electrochemical kinetics will increase in the region of mixed kinetics. We suppose that the data obtained can also be of practical importance for the zinc electrolysis technology. The data obtained in this research on the electrochemical parameters of hydrogen discharge in a wide range of potentials on cathodes made of different metals as well as on the effect of electrolyte acidity on the behavior of surfactants during electrolysis will expand knowledge about the zinc electrolysis technology.
Publisher
National University of Science and Technology MISiS
Reference31 articles.
1. Ponomarev D.A., Plotnikova M.D., Shein A.B., Rubtsov A.E. Issledovanie zashchitnogo deistviya proizvodnykh tiazola i tiadiazola na malouglerodistoi stali v rastvore solyanoi kisloty. Vestn. Perm. un-ta. Ser. Khimiya. 2018. Vyp. 3(31). S. 349—359. DOI: 10.17072/2223-1838-2018-3-349-359. Ponomarev D.A., Plotnikova M.D., Shein A.B., Rubtsov A.E. Study of the protective action of thiazole and thiadiazole derivatives on low-carbon steel in hydrochloric acid solution. Vestnik Permskogo universiteta. Ser. Khimiya. 2018. No. 3(31). P. 349—359 (In Russ.).
2. Shein A.B., Plotnikova M.D., Rubtsov A.E. Zashchitnye svoistva ryada proizvodnykh tiadiazola v rastvorakh sernoi kisloty. Izvestiya vuzov. Khimiya i khim. tekhnologiya. 2019. T. 62 (7). S. 123—129. DOI: 10.6060/ivkkt.20196207.5968. Shein A.B., Plotnikova M.D., Rubtsov A.E. Protective properties of a number of thiadiazole derivatives in sulfuric acid solutions. Izv. vuzov. Khimiya i khimicheskaya tekhnologiya. 2019. Vol. 62 (7). 123—129 (In Russ.).
3. Vigdorovich V.I., Tsygankova L.E., Balybin D.V., Kichigin V.I., Kryl'skii D.V. Kinetika i priroda zamedlennoi stadii reaktsii katodnogo vydeleniya vodoroda na zheleze v vodnykh i vodno-etilenglikolevykh rastvorakh NSl v prisutstvii o-ftorfenilbiguanidina. Elektrokhimiya. 2013. T. 49. No. 11. S. 1045— 1052. DOI: 10.7868/S0424857013110133. Vigdorovich V.I., Tsygankova L.E., Balybin D.V., Kichigin V.I., Kryl’Skii D.V. Kinetics and nature of the slow stage of cathodic hydrogen evolution on iron in aqueous and water-ethylene-glycol solutions of HCl in the presence of o-fluorophenylbiguanidine. Russ. J. Electrochemistry. 2013. Vol. 49. No. 11. P. 1045—1052.
4. Mokrushin M.A., Shein A.B., Rubtsov A.E. Poisk potentsial'nykh ingibitorov korrozii v ryadu serosoderzhashchikh organicheskikh soedinenii. Vestn. Perm. un-ta. Ser. Khimiya. 2017. T. 27. Vyp. 3. C. 271—278. DOI: 10.17072/2223-1838-2017-3-271-278. Mokrushin M.A., Shein A.B., Rubtsov A.E. The search of potential corrosion inhibitors in a series of sulfurcontaining organic substances. Vestnik Permskogo universiteta. Ser. Khimiya. 2017. Vol. 27. No. 3. P. 271—278 (In Russ.).
5. Solmaz R., Anzinger A., Paschen P. Investigation of adsorption and inhibitive effect of 2-mercaptothiazoline on corrosion of mild steel in hydrochloric acid media. Electrochimica Acta. 2008. Vol. 53. No. 20. P. 5941—5952. DOI: 10.1016/j.electacta.2008.03.055.