MODIFICATION OF YSZ PROPERTIES BY HIGH ENERGY IONS OF ARGON AND OXYGEN

The influence of high-energy oxygen and argon ions irradiation on the structure and conductive properties of YSZ of various composition has been studied. It was shown that irradiation with YSZ ions causes minor failures in the structure of the near-surface regions of complex oxide, but does not cause any change in the type of crystal lattice. Apparently, the latter is due to the fact that both defects and implanted ions are mainly located quite deep from the surface of YSZ. Along with this, high radiation resistance of YSZ near-surface layers with the concentration of Y₂O₃ of 10 and 15 mol. %, is apparently due to the high concentration of oxygen vacancies in the initial unirradiated materials, which act as effective recombination centers for defects formed during irradiation. In the samples of ZrO₂ + 3 mol. % Y₂O₃ composition, the concentration of vacancies is lower, and during irradiation there is a notable yield of oxygen from YSZ along with recombination. This leads to decrease in oxygen concentration and increase in zirconium concentration on the surface of the complex oxide. The values of the activation energies of the oxygen-ionic conductivity of the studied materials have been determined. It was noted that irradiation of YSZ with heavy ions in some cases can cause the improvement in the oxygen-ionic conductivity of these materials.

1. Iwahara H., Uchida H., Tanaka S. High temperature proton conducting solids oxide fuel cells using various fuels // J. Appl. Electrochem. – 1986.–Vol. 16. – P. 663–668.

2. Pal’guev S.F. High-Temperature Solid State Protonic Electrolytes: A Literature Review. Yekaterinburg, Ural. Department of RAN. – 1998. – 82 p.

3. Bauerle J.E., Hrizo J. Interpretation of the resistivity temperature dependence of high purity (ZrO2) 0.90 (Y2O3) 0.10 // J. Phys.Chem. Solids. – 1969. – Vol.30. – P. 565.

4. Solier J.D., Cachadina I., Dominques-Rodriques A. Ionic conductivity of ZrO2–12 mol % Y2O3 single crystals // Phys. Rev. B. – 1993. – Vol.48. – P. 3704.

5. Горшков О.Н. О формировании нанокластеров циркония в стабилизированном диоксиде циркония при облучении ионами. // Вестник Нижегородского университета им. Лобачевского. 2010. – №5 (2).– С. 271–278.

6. W.L. Gong, W. Lutze, R.C. Ewing. Zirconia ceramics for excess weapons plutonium waste // Journal of Nuclear Materials. – 2000. – V. 277. – Issues 2–3. – P. 239–249.

7. Ziegler J.F., Biersack J.P., Ziegler M.D., SRIM – The Stopping and Range of Ions in Matter. – 2012.– 398 p

8. Aksenova T.I., Khromushin I.V., Zhotabaev Zh.R., Bukenov K.D., Berdauletov A.K, Medvedeva Z.V. Thermodesorption study of barium and strontium cerates // Solid State Ionics. – 2003. – Vol. 162–163. – P. 31–36.

9. Jacobson A.J. Materials for solid oxide fuel cells // Chem. Mater. –2010. –V. 22. – P. 660–674.

10. Lyskov N.V., Kolchina L.M., Pestrikov P.P., Mazo G.N., Antipov E.V. Electrotransport Properties of SOFC Cathode Materials Based on Lanthanum Cuprate Doped with Praseodymium and Strontium Oxides // Russian Journal of Electrochemistry. – 2016. – V. 52. – P. 642–647.

11. Boivin J.C., Mairesse G. Recent material developments in fast ion conductors // Chem. Mater. –1998. – V. 10. – P. 2870–2888.

12. Хромушин И.В., Аксенова Т.И. Влияние низкоэнергетических ионов аргона на проводящие свойства YSZ. // Вестник НЯЦ РК. – 2017. – выпуск 1. – С. 55–61.

13. Токий Н.В., Перекрестов Б.И., Савина Д.Л., Даниленко И.А. Концентрационная и температурная зависимости энергии миграции кислорода в стабилизированном иттрием диоксиде циркония // Физика твердого тела. – 2001. – Т. 53. – Вып.9. – С. 1732–1736.