THE ION IMPLANTATION AS THE METHOD FOR IMPROVING THE CORROSION RESISTANCE AND ACTIVITY OF ELECTROCATALYSTS (REVIEW)

The paper deals with the processes of producing materials with new electrochemical properties by ion implantation method. Both the positive and negative processes accompanied implantation are considered. The paper generalizes the promising examples of the use of ion implantation method for improving the corrosion resistance and activity of electrocatalysts.

ion implantation, electrocatalysis, electrocatalysts, protection against corrosion, oxidation, electrochemical sensors

1. Rutherford E. Retard ation of the α particle from radium in passing through matter. Philosophical Maga-zine Series 6, 1906, vol. 12, no. 68, pp. 134–146 (in Eng.).

2. Ohl R.S. Properties of ionic bombarded silicon. Bell System Technical Journal, 1952, vol. 31, no. 1, pp. 104–121 (in Eng.).

3. Shockley W. Forming semiconductive devices by ionic bombardment. Patent USA. US2787564 (A). 1957 (in Eng.).

4. Bredov M.M., Komarova R.F., Regel A.R. Issledovanie izmenenij vyprâmlâûŝih svojstv točečnogo kontakta metall-poluprovodnik pod vliâniem oblučeniâ poluprovodnika ionami ŝeločnyh metallov. DAN USSR, 1954, vol. 99, no. 1, pp. 69–75 (in Russ.).

5. Bredov M.M., Lepilin V.A., Shestakov I.B., Shah-Budagov A.L. Vliânie tipa ionov na izmenenie èlektričeskih svojstv poverhnosti poluprovodnikov proizvedennoe oblučeniem ionami srednih ènergij. Fizika tverdogo tela, 1961, vol. 3, pp. 267–272 (in Russ.).

6. Bredov M.M., Muromsky A.B. Ob izmenenii poverhnostnyh svojstv p-kremniâ pri oblučenii ionami litiâ. FTT, 1962, vol. IV, pp. 562–564 (in Russ.).

7. Gusev V.M., Guseva M.I., Elistratov N.P., Ikonnikov D.S. Bystroe vvedenie ionov dejteriâ v metally. Ž.teh.fiziki, 1961, vol. 31, pp. 749–750 (in Russ.).

8. Gusev V.M., Titov V.V., Guseva M.I., Kurinnyj V.I. Obrazovanie kremnievogo konvertora fotoèlektričeskoj ènergii metodom bombardirovki. FTT, 1965, vol. 7, no. 7, pp. 2077–2081 (in Russ.).

9. Gusev V.M., Busharov N.P., Naftulin S.M. Ionnyj uskoritel’ ILU na 100 kèV s separaciej ionov po masse. Pribory i tehnika èksperimenta, 1969, no. 4, pp. 19–25 (in Russ.).

10. Vladimirov B. G., Zalavutdinov R. H., Gorodecky A. E., Lavrova G. N., Fomin A.V., Stolyarova V.G., Guseva M.I., Zhiltsova O.A., Tomashov N. Sposob obrabotki poverhnostnyh sloev izdelij iz titana. Author's certificate (21) 4937847/21 (22) 20.05.91 (46) 23.07.93. // Bul. Moscow, 27 (71) (in Russ.).

11. Gusev V.M., Guseva M.I., Demakov K.D. Gosudarstvennaâ premiâ USSR v oblasti nauki i tehniki “Razrabotka i osvoenie serijnogo vypuska special’nogo tehnologičeskogo ionno-lučevogo oborudovaniâ; razrabotka osnov promyšlennoj tehnologii ionnoj implantacii dlâ serijnogo proizvodstva i sozdaniâ novyh tipov poluprovodnikovyh priborov i integral’nyh shem dlâ narodnogo hozâjstva i oboronnoj tehniki” (in Russ.).

12. Belyj A.V. et al. Primenenie ionnogo legirovaniâ dlâ povyšeniâ èkspluatacionnyh harakteristik detalej mašin i oborudovaniâ, v tom čisle lopatok turbin. Minsk, 1985, 44 p. (in Russ.).

13. Ionnaâ implantaciâ. Pod red. Dzh.K. Hirvonen. Moscow: Metallurgiâ Publ., 1985, 392 p. (in Russ.).

14. Didenko A.N. et al. Vozdejstvie pučkov zarâžennyh častic na poverhnost’ metallov i splavov. Moscow, 1987, 184 p. (in Russ.).

15. Ionnaâ implantaciâ i lučevaâ tehnologiâ. Pod red. Dz.S. Vilâmsa, Dzh. M. Pouta. Kiev: Naukova dumka Publ., 1988, 360 p. (in Russ.).

16. Fedotov A.A., Grigoriev S.A., Lyutikova E.K., Millet P., Fateev V.N. Characterization of carbon-supported platinum nano-particles synthesized using magnetron sputtering for application in PEM electrochemical systems//Int. J. Hydrogen Energy. 2013. Vol. 38. P. 426-430.

17. Fateev V., Alekseeva O., Elena Lutikova E., Porembskiy V., Nikitin S., Mikhalev A. New physical technologies for catalyst synthesis and anticorrosion protection//Int. J. Hydrogen Energy. 2016. Vol. 41. P. 10515-10521.

18. Liang F., Jia M., Hua J. Pt-implanted indium tin oxide electrodes and their amperometric sensor applica tions for nitrite and hydrogen peroxide//Electrochimica Acta. 2012. Vol. 75. P. 414-419.

19. Walther S.R., Pedersen B.O. and McKenna C.M. Ion sources for commercial ion lmplanter applications https://accelconf.web.cern.ch/accelconf7p91/PDF/PAC199 1_2088.PDF

20. Pylypenko S., Queen A., Olson T. S., Dameron A., O’Neill K., Neyerlin K. C., Pivovar B., Dinh H. N., Ginley D.S., Gennett T., and O’Hayre R. Tuning carbon-based fuel cell catalyst support structures via nitrogen functionalization. I. Investigation of structural and compositional modification of highly oriented pyrolytic graphite model catalyst supports as a function of nitrogen implantation dose//J. Phys. Chem. C. 2011. Vol. 115, No 28. P. 13667-13675.

21. Perini L., Durante C., Favaro M., Agnoli S., Granozzi G., Gennaro A., Electrocatalysis at palladium nanoparticles: Effect of the support nitrogen doping on the catalytic activation of carbon halogen bond//Applied Catalysis B: Environmental. 2014. Vol. 144. P. 300-307.

22. Primak W. Radiation induced cavities and exfoliation//J. Appl. Phys. 1963. Vol. 34. P. 3630-3631.

23. Santala M. K., Radmilovic V., Giulian R., Ridgway M. C., Glaeser A. M., Gronsky R. Precipitate orientation relationships in Pt-implanted sapphire//Scripta Materialia. 2010. Vol. 62. P. 187-190.

24. Pivin J.C., Rizza G. Competing processes of clustering and mixing of noble metal embedded in silica under ion irradiation//Thin Solid Films. 2000. Vol. 366. P. 284-293.

25. Guan W., Peng N., Jeynes C., Ghatak J., Peng Y., Ross I. M., Bhatta U. M., Inkson B. J., Mübus G. Fabrication and characterisation of embedded metal nanostructures by ion implantation with nanoporous anodic alumina masks//Nuclear Instruments and Methods in Physics Research B. 2013. Vol. 307. P. 273-276.

26. Battaglin G., Bertoncello R., Casarin M., Cattaruzza E., Mattei G., Mazzoldi P., Trivillin F., Urbani M. Pd ion implantation in silica and alumina: chemical and physical interactions//Journal of NonCrystalline Solids. 1999. Vol. 253. P. 251-260.

27. Jiao J., Liu C., Chen Q., Li S., Hu J., Li Q. Surface modification of indium tin oxide films by amino ion implantation for the attachment of multi-wall carbon nanotubes//Applied Surface Science. 2010. Vol. 257. P. 752-755.

28. Liu C., Chen Q., Jiao J., Li S., Hu J., Li Q. Surface modification of indium tin oxide films with Au ions implantation: Characterization and application in bioelectrochemistry//Surface & Coatings Technology. 2011. Vol. 205. P. 3639-3643.

29. Yu Y., Wang T., Fu Y., Su W., Hu J. Platinum nanoparticles ion-implanted-modified indium tin oxide electrode for electrocatalytic oxidation of formaldehyde//Int. J. Hydrogen Energy. 2014. Vol. 39. P. 17617-17621.

30. Tian H., Jia M., Zhang M., Hu J. Nonenzymatic glucose sensor based on nickel ion implanted-modified indium tinoxide electrode//Electrochimica Acta. 2013. Vol. 96. P. 285-290.

31. Tian H., Jia M., Zhang M., Hu J., Li S., Ji X., Liu C., Cao W., Hua J., Li Q. Direct electrochemistry of cytochrome c at a novel gold nanoparticles-attached NH2 ions implantation-modified indium tin oxide electrode//Journal of Electroanalytical Chemistry. 2009. Vol. 633. P. 273-278.

32. Salvadori M.C., Teixeira F.S., Sgubin L.G., Cattani M., Brown I.G. Surface modification by metal ion implantation forming metallic nanoparticles in an insulating matrix//Applied Surface Science. 2014. Vol. 310. P. 158-163.

33. Santala M.K., Radmilovic V., Giulian R., Ridgway M.C., Glaeser A.M., Gronsky R. Precipitate orientation relationships in Pt-implanted sapphire//Scripta Materialia. 2010. Vol. 62. P. 187-190.

34. Mariani-Regula G., Pichaud B., Godey S., Ntsoenzok E., Perner O., Bouayadi R.E. Gettering of platinum by cavities induced in silicon by high energy implantation of HE ions//Materials Science and Engineering. 2000. Vol. B71. P. 203-206.

35. Fenfen Liang, Mingzhe Jia, Jingbo Hu. Pt-implanted indium tin oxide electrodes and their amperometric sensor applications for nitrite and hydrogen peroxide//Electrochimica Acta. 2012. Vol. 75. P. 414-419.

36. Shulov V.A. Novikov A.S., Paikin A.G., Ryabchikov A.I. Erosion resistance of refractory alloys modified by ion beams//Surface & Coatings Technology. 2007. Vol. 201. P. 8105-8111.

37. Pivin J.C., Rizza G. Competing processes of clustering and mixing of noble metal films embedded in silica under ion irradiation//Thin Solid Films. 2000. Vol. 366. P. 284-293.

38. Battaglin G., Bertoncello R., Casarin M., Cattaruzza E., Mattei G., Mazzoldi P., Trivillin F., Urbani M. Pd ion implantation in silica and alumina: chemical and physical interactions//Journal of Non-Crystalline Solids. 1999. Vol. 253. P. 251-260.

39. Perini L., Durante Ch., Favaro M., Agnoli S., Granozzi G., Gennaro A. Electrocatalysis at palladium nanoparticles: Effect of the support nitrogen doping on the catalytic activation of carbon halogen bond//Applied Catalysis B: Environmental. 2014. Vol. 144. P. 300-307.

40. Santala M.K., Radmilovic V., Giulian R., Ridgway M.C., Glaeser A.M., Gronsky R. Precipitate orientation relationships in Pt-implanted sapphire//Scripta Materialia. 2010. Vol. 62. P. 187-190.

41. Salvadoria M.C., Teixeiraa F.S., Sgubina L.G., Cattania M., Brown I.G., Surface modification by metal ion implantation forming metallic nanoparticles in an insulating matrix//Applied Surface Science. 2014. Vol. 310. P.158-163.

42. Liang F., Tian H., Jia M., Hu J. Pt nanoparticles ion-implanted onto indium tin oxide electrodes and their electrocatalytic activity towards methanol//Journal of Power Sources. 2013. Vol. 225. P. 9-12.

43. Interactions of Ions with Matter ww.srim.org

44. Stimming U. Photoelectrochemical studies of passive films//Electrochim Acta. 1986. Vol. 31. P. 415-429.

45. Зарубежные аналоги сталей http://www.steelser.ru/guide/foreign-articles-analog

46. Antunes R.A., Oliveira M.C.L., Ett G., Ett V. Corrosion of metal bipolar plates for PEM fuel cells // International journal of hydrogen energy. 2010. Vol. 35. P. 3632 - 3647; Jung H.Y., Huang S.Y., Ganesan P., Popov B.N. Performance of gold-coated titanium bipolar plates in unitized regenerative fuel cell operation // J. Power Sources. 2009. Vol. 194. P. 972-975.

47. Muthukumaran V., Selladurai V., Nandhakumar S., Senthilkumar M. Experimental investigation on corrosion and hardness of ion implanted AISI 316L stainless steel//Materials and Design. 2010. Vol. 31. P. 2813-2817.

48. Jung H.Y., Huang S.Y., Ganesan P., Popov B.N. Performance of gold-coated titanium bipolar plates in unitized regenerative fuel cell operation//J. Power Sources. 2009. Vol. 194. P. 972-975.

49. Feng K., Cai X., Li Z., Chu P.K. Improved corrosion resistance of stainless steel 316L by Ti ion implantation//Materials Letters. 2012. Vol. 68. P. 450-452.

50. Lee J.-B. and Oh I.H. Electrochemical characteristics and interfacial contact resistance of multilayered ti/tin coating for metallic bipolar-plate of polymer electrolyte membrane fuel cells//Met. Mater. Int. 2014. Vol. 20. №. 4. P. 629-639.

51. Vaseckaya L.A. Ionnaâ implantaciâ kak sposob povyšeniâ èkspluatacionnoj stojkosti melkorazmernogo stal’nogo instrumenta. Vostočno-Evropejskij žurnal peredovyh tehnologij, 2013, vol. 5/6, no. 66, pp. 7–11 (in Russ.).

52. Feng K., Shen Y., Liu D., Chu P.K., Cai X. NiCr Co-implanted 316L stainless steel as bipolar plate in polymer electrolyte membrane fuel cells. International journal of hydrogen energy, 2010, vol. 35, pp. 690–700 (in Eng.).

53. Ovchinnikov V.V., Kozlov D.A., Yakutina S.V. Vliânie ionnoj implantacii medi na svojstva konstrukcionnoj stali 30HGSN2A. Upročnâûŝie tehnologii i pokrytiâ, 2009, no. 10, pp. 16–23 (in Russ.).

54. Yakutina S.V. Povyšenie èkspluatacionnyh svojstv detalej iz stali 30HGSN2A implantaciej ionov medi i svinca: Ph.D. thesis (engineering). Moscow, 2011, 20 p (in Russ.).

55. Analogi Titan, Splav titana – USA. Available at: http://www.splavkharkov.com/z_mat_class.php?type_id=17&zcountry=20 (in Russ.).

56. Krupa D., Baszkiewicz J., Jezierska E., Mizera J., Wierzchon T., Barcz A., Fillit R. Effect of nitrogenion implantation on the corrosion resistance of OT-4-0 titanium alloy in 0.9% NaCl environment//Surface and Coatings Technology. 1999. Vol. 111. P. 86-91.

57. Liu Y.Z., Zu X.T., Qiu S.Y., Cao J., Li C.X., Huang X.Q., Wei C.F. Phase formation and modification of corrosion property of nitrogen implanted Ti-Al-V alloy//Vacuum. 2006. Vol. 81. P. 71-76.

58. Liu Y.Z., Zu X.T., Cao J., Wang L., Li C.X., Huang X.Q. Phase formation in nitrogen ion implanted Ti-Al-Zr alloy and modification of corrosion property//Nuclear Instruments and Methods in Physics Research B. 2005. Vol. 237. P. 543-54.

59. Savaloni H., Khojier K., Torabi S. Influence of N+ ion implantation on the corrosion and nano-structure of Ti samples//Corrosion Science. 2010. Vol. 52. P. 1263-1267 (in Eng.).

60. Savonov G.S., Ueda M., Oliveira R.M., Otani C. Electrochemical behavior of the Ti6Al4V alloy implanted by nitrogen PIII//Surface and Coatings Technology. 2011. Vol. 206. P. 2017-2020.

61. Ali N., Fulazzaky M.A., Mustapa M.S., Ghazal M.I., Ridha M., Sujitno T. Assessment of fatigue and corrosion fatigue behaviors of the nitrogen ion implanted CpTi//International Journal of Fatigue. 2014. Vol. 61. P. 184-190.

62. Gordin D.M., Busardo D., Cimpean A., Vasilescu C., Höche D., Drob S.I., Mitran V., Cornen M., Gloriant T. Design of a nitrogen-implanted titanium-based superelastic alloy with optimized properties for biomedical applications//Materials Science and Engineering: C. 2013. Vol. 33, iss. 7. P. 4173-4182.

63. Kopac J., Jackson M.J., Waqar A. Review: titanium and titanium alloy applications in medicine//Int. J. Nano Biomater. 2001. Vol. 1. P. 3-34.

64. Mändl S., Sader R., Thorwart G., Krause D., Zeilhofer H.-F., Horch H. H., Rauschenbach B. Investigation on plasma immersion ion implantation treated medial implants//Biomolecular Eng. 2002. Vol. 19. P. 129-132.

65. Qin H. at al. In vitro and in vivo anti-biofilm effects of silver nanoparticles immobilized on titanium//Biomaterials. 2014. Vol. 35, iss. 33. P. 9114-9125.

66. Jin G., Qin H., Cao H., Qian S., Zhao Y, Peng X., Zhang X., Liu X., Chu P. K. Synergistic effects of dual Zn/Ag ion implantation in osteogenic activity and antibacterial ability oftitanium//Biomaterials. 2014. Vol. 35, iss. 27. P. 7699-7713.

67. Hempel F., Finke B., Zietz C., Bader R., Weltmann K.-D., Polak M. Antimicrobial surface modification of titanium substrates by means of plasma immersion ion implantation and deposition of copper//Surface and Coatings Technology. 2014. Vol. 256. P. 52-58.

68. Hongxi L., Qian X., Xiaowei Z., Chuanqi W., Baoyin T. Wear and corrosion behaviors of Ti6Al4V alloy biomedical materials by silver plasma immersion ionimplantation process//Thin Solid FilmsVolume. 2012. Vol. 521. P. 89-93.

69. Fateev V., Alekseeva O., Lutikova E., Porembskiy V., Nikitin S., Mikhalev A. New physical technologies for catalyst synthesis and anticorrosion protection//Int. J. Hydrogen Energy. 2016. Vol. 41, No 25. P.10515-10521.

70. Куликова Л.Н., Фатеев В.Н., Баттисти А.Де, Русанов В.Д. Электрохимическое поведение диоксида иридия, модифицированного методом ионной имплантации//Электрохимия. 1996. Т. 32, № 6. С. 749-753.

71. Фатеев В.Н., Гусева М.И., Пахомов В.П. и др. Синтез анодных электрокаталитических покрытий методом имплантации атомов отдачи//Электрохимия. 1990. Т. 26, № 1. С. 74-76.

72. Fateev V., Glukhov A., Nikitin S. et. al. “New Physical Technologies for Catalyst Synthesis and Anticorrosion Protection” 5th European PEFC & H2 Forum, Luzern, 30 June -3 July 2015. Chapter 04. Sessions A06, A09, A13. P. 89-98.

73. Maruseva I.V., Pushkarev A.S., Mihalev A.I., Fateev V.N., Grigorev S.A. Nekotorye vozmožnosti ionnoj implantacii dlâ povyšeniâ korrozionnoj stojkosti i katalitičeskoj aktivnosti titanovyh kollektorov toka dlâ èlektrolizerov s TPÈ. Sbornik trudov rossijskoj konferencii “Fiziko-himičeskie problemy vozobnovlâemoj ènergetiki”. 16–18 November 2015, Sankt-Peterburg, p. 237 (in Russ.).

74. Fenfen Liang, Huifeng Tian, Mingzhe Jia, Jingbo Hub. Pt nanoparticles ion-implanted onto indium tin oxide electrodes and their electrocatalytic activity towards methanol. Journal of Power Sources, 2013, vol. 225, pp. 9–12 (in Eng.).

75. Kato S., Yamaki T., Yamamoto S., Hakoda T., Kawaguchi K., Kobayashi T., Suzuki A., Terai T. Prepara-tion of tungsten carbide nanoparticles by ion implantation and electrochemical etching. Nuclear Instruments and Methods in Physics Research B, 2013, vol. 314, pp. 149–152 (in Eng.).

76. Kulikova L.N., Fateev V.N., Pahomov V.P., Potapova G.F., Kasatkin È.V. Modificirovannye implantaciej platinovye i platinotitanovye èlektrody. Èlektrohimiâ, 1990, vol. 26, no. 10, pp. 1048–1050 (in Russ.).

77. Kulikova L.N., Fateev V.N., Battisti A.De, Rusanov V.D. Èlektrohimičeskoe povedenie dioksida iridiâ, modificirovannogo metodom ionnoj implantacii. Èlektrohimiâ, 1996, vol. 32, no. 6, pp. 749–753 (in Russ.).

78. Semiconductor Our Products. Available at: http://www.semisvs.com/vsea-01.html (in Eng.).

79. OOO «ÈNERGOAVANGARD» kompleksnoe osnaŝenie predpriâtij. Available at:http://eav.su/catalog/ionnaya-implantaciya (in Russ.).

80. ULVAC. Available at: http://www.ulvac.com (in Eng.).