ХІМІЯ, ФІЗИКА ТА ТЕХНОЛОГІЯ ПОВЕРХНІ

ISSN 2518-1238 (Online), ISSN 2079-1704 (Print)

Одержані темплатним золь-гель методом мезопористі нанорозмірні порошки діоксиду титану, модифікованого йонами 3d металів, досліджено методами PФЕС и ТПВ. Встановлено валентний стан йонів металів на поверхні діоксиду титану. Аналіз термопрограмованого відновлення воднем показав, що відновлювальна здатність Mⁿ⁺/TiO₂ залежить від методу синтезу та умов термообробки. Показано, що формування Ti–O–M зв'язків при золь-гель синтезі, присутність нейонного триблоккополімера Pluronic P123 як органічного темплату і термообробка при 550°C стабілізують високодисперсний стан металовмісних сполук. Методами PФЕС та ТПВ показано співіснування дво- та тривалентних йонів металів для Mⁿ⁺/TiO₂, де M=Co, Ni, Mn, та моно- і дивалентного стану у випадку Cu/TiO₂.

мезопористі Mn+/TiO2 порошки; Con+; Nin+; Mnn+ та Cun+ перехідні метали; РФЕС; H2-TПВ

1. Umebayashi T., Yamaki T., Itoh H., Asai K. Analysis of electronic structures of 3d transition metal-doped TiO₂ based on band calculations. J. Phys. Chem. Solids . 2002. 63: 1909.

2. Carp O., Huisman C.L., Reller A. Photo-induced reactivity of titanium dioxide. Prog. Solid State Chem. 2004. 32 (1): 33.

3. Ghasemi S., Rahimnejad S., Rahman Setayesh S., Rohani S., Gholami M.R. Transition metal ions effect on the properties and photocatalytic activity of nanocrystalline TiO₂ prepared in an ionic liquid. J. Hazard. Mater. 2009. 172(2): 1573.

4. López R., Gómez R., Lianos M.E. Photophysical and photocatalytical properties of nanosized copper-doped titania sol-gel catalysts. Catal. Today. 2009. 148 : 103.

5. Gomathi Devi L., Girish Kumar S. Influence of physicochemical–electronic properties of transition metal ion doped polycrystalline titania on the photocatalytic degradation of Indigo Carmine and 4-nitrophenol under UV/solar light. Appl. Surf. Sci . 2011. 257(7): 2779.

6. Kim H.-J., Lu L., Kim J.-H. Lee C.-H., Hyeon T., Choi W., Lee H.-I. UV Light induced photocatalytic degradation of cyanides in aqueous solution over modified TiO2. Bull. Korean Chem. Soc . 2001. 22(12): 1371.

7. Navío J.A., Juan J.T., Djedjeian P., Padrón J.R., Padrón J.R., Rodrı́guez D., Litter M.I. Iron-doped titania powders prepared by a sol-gel method. Part II: Photocatalytic properties. Appl. Catal. A . 1999. 178(2): 191.

8. Zhang F., Jin R., Chen J., Shao C. Shao C., Gao W., Li L., Guan N. High photocatalytic activity and selectivity for nitrogen in nitrate reduction on Ag/TiO2 catalyst with fine silver clusters, J. Catal . 2005. 232(2): 424.

9. Sá J., Aguüera C. A., Gross S., Anderson J.A. Photocatalytic nitrate reduction over metal modified TiO₂. Appl. Catal. B . 2009. 85: 192.

10. Kelyp A.A., Petrik I.S., Losovsky А.V. Synthesis of photocatalytically active dispersions ТіО₂/Мn+ (М=Co, Ni, Mn, Cu) for denitrification of water. Nanosystems, Nanomaterials, Nanotechnologies . 2012. 10(4): 789.

11. Suriye K., Praserthdam P., Jongsomjit B. Effect of surface sites of TiO₂ support on the formation of cobalt-support compound in Co/TiO₂ catalysts. Catal. Comm. 2007. 8: 1772.

12. Duvenhage D.J., Coville N.J. Fe:Co/TiO₂ bimetallic catalysts for the Fischer–Tropsch reaction Part 2. The effect of calcination and reduction temperature. Appl. Catal. A . 2002. 233: 63.

13. Coville N.J., Li J. Effect of boron source on the catalyst reducibility and Fischer-Tropsch synthesis activity of Co/TiO₂ catalysts. Catal. Today . 2002. 71: 403.

14. Kelyp A.A., Smirnova N.P., Oleksenko L.P. et al. Catalytic activity of Со/SіО₂ and Со/ТіО₂ nanosized systems in the oxidation of carbon monoxide. Rus. J. Phys. Chem. A . 2013. 87: 1015.

15. Petrik I., Kelyp О., Vorobets V. Smirnova N., Frolova O., Oranska O., Kolbasov G., Eremenko A. Synthesis, optical, electro- and photocatalytic properties of nanosized TiO₂ -films modified with transition metal (Co, Ni, Mn, Cu)-ions. Hìm. Fìz. Tehnol. Poverhnì. 2011. 2(4): 418.

16. Kelyp О., Petrik I., Vorobets V., Smirnova N.P., Kolbasov G.Ya. Sol-gel synthesis and characterization of mesoporous TiO2 modified with transition metal ions (Co, Ni, Mn, Cu). Hìm. Fìz. Tehnol. Poverhnì. 2013. 4(1): 105.

17. Krylova G.V., Gnatyuk Yu.I., Smirnova N.P., Eremenko A.M., Gun’ko V.M. Ag nanoparticles deposited onto silica, titania and zirconia mesoporous films synthesized by sol-gel template method. J. Sol-Gel Sci . Technol. 2009. 50(2): 216.

18. Garbassi F., Balducci L. Preparation and characterization of spherical TiO₂-SiO₂ particles. Micropor. Mesopor. Mater. 2001. 47 (2): 51.

19. Keränen J., Guimon C., Iiskola E., Aurouxa A., Niinistö L. Atomic layer deposition and surface characterization of highly dispersed titania/silica-supported vanadia catalysts, Catal. Today . 2003. 78(1): 149.

20. Wagner C.D., Moulder J.F., Davis L.E., Riggs W.M. Handbook of X-ray Photoelectron Spectroscopy. (New York: Perkin-Elmer Corp., 1979).

21. Nefedov V.I. Roentgenelectronic spectroscopy of chemical compounds: Handbook. (Мoscow: Khimija, 1984). [in Russian].

22. Nowitzki T., Carlsson A.F., Martyanov O., Naschitzki M., Zielasek V., Risse T., Schmal M., Freund H.-J., Bäumer M. Oxidation of alumina-supported Co and Co–Pd model catalysts for the Fischer-Tropsch reaction. J. Phys. Chem. C . 2007. 111(24): 8566.

23. Jeong B.-S., Heo Y.W., Norton D.P. Spatial distribution and electronic state of Co in epitaxial anatase CoxTi_1-xO₂ thin films grown by reactive sputtering. Appl. Phys. Lett. 2004. 84: 2608.

24. Guo Q., Liu Yu. MnOx modified Co₃O₄-CeO₂ catalysts for the preferential oxidation of CO in H₂-rich gases. Appl. Catal. B. 2008. 82: 19.

25. Chu W., Chernavskii P.A., Gengembre L. Pankina G.A., Fongarland P., Khodakov A.Y. Cobalt species in promoted cobalt-alumina-supported Fischer-Tropsch catalysts. J. Catal . 2007. 252: 215.

26. Berenguer R., Valdes-Solis T., Fuertes A.B., Quijada C., Morallón E. Cyanide and phenol oxidation on nanostructured Co₃O₄ electrodes prepared by different methods. J. Electrochem. Soc. 2008. 155(7): 1.

27. Barakat M.A., Hayes G., Shan S.I. Effect of cobalt doping on the phase transformation of TiO₂ nanoparticles. J. Nanosci. Nanotech . 2005. 10: 1.

28. Tang Q., Zhang Q., Wang P., Wang Y., Wan H. Characteristics of cobalt oxide nanoparticles within faujasite zeolites and the formation of metallic cobalt. Chem. Mater . 2004. 16(10): 1967.

29. Chupin C., van Veen A.C., Konduru M., Després J., Mirodatos C. Identity and location of active species for NO reduction by CH over Co-ZSM-5. J. Catal. 2006. 241 (1): 103.

30. Feng Y., Li L., Niu Sh., Qua Y., Zhang Q., Li Y., Zhao W., Li H., Shi J. Controlled synthesis of highly active mesoporous Co₃O₄ polycrystals for low temperature CO oxidation, Appl. Catal. B. 2012. 111–112(12): 461.

31. Rizhi Ch., Yan D., Weihong X., Nanping X. The effect of titania structure on Ni/TiO2 catalysts for p-nitrophenol hydrogenation. Chinese J. Chem. Eng . 2006. 14: 665.

32. Wu Y., He Y., Chen T., Weng W., Wan H. Low temperature catalytic performance of nanosized Ti–Ni–O for oxidative dehydrogenation of propane to propene. Appl. Surf. Sci . 2006. 252: 5220.

33. Hoffer B.W., van Langeveld A.D., Janssens J.-P., Bonné R.L.C., Lok C. M., Moulijn J.A. Stability of highly dispersed Ni/Al₂O₃ catalysts: effect of pretreatment. J. Catal. 2000. 192(2): 432.

34. Kantcheva M., Kucukkal M.U., Suzer S. Spectroscopic investigation of species arising from CO chemisorrption on titania-supported manganese. J. Catal. 2000. 190 : 144.

35. Luo, J.-Y., Meng M., Li X., Li X.-G., Zha Y.-Q., Hu T.-D., Xie Y.-N., Zhang J. Mesoporous Co₃O₄–CeO₂ and Pd/Co₃O₄–CeO₂ catalysts: Synthesis, characterization and mechanistic study of their catalytic properties for low-temperature CO oxidation. J. Catal . 2008. 254(2): 310.

36. Oliveira H.A., Franceschini D.F., Passos F.B. Support Effect on Carbon nanotube growth by methane chemical vapor deposition on cobalt catalysts. J. Braz. Chem. Soc . 2012. 23: 868.

37. Tang Ch.-W., Wang Ch.-B., Chien Sh.-H. Characterization of cobalt oxides studied by FT-IR, Raman, TPR and TG-MS. Thermochimica Acta. 2008. 473 : 68.

38. Wang C.-B., Tang C.-W., Tsai H.-Ch, Chien Sh.-H. Characterization and catalytic oxidation of carbon monoxide over supported cobalt catalysts. Catal. Lett . 2006. 107: 223.

39. Morales F., de Groot F.M.F., Gijzeman O.L.J., Mens A., Stephan O., Weckhuysen B.M. Mn promotion effects in Co/TiO₂ Fischer-Tropsch catalysts as investigated by XPS and STEM-EELS. J. Catal . 2005. 230(2): 301.

40. Loc L.C., Huan Ng.M., Dung Ng.K. Phuc Ng.H.H., Thoang H.S. Study on methanation of carbon monoxide over catalysts NiO/TiO₂ and NiO/g-Al2 O3. Adv. Natural Sci. 2006. 7(2): 91.

41. Ettireddy P., Ettireddy N., Mamedov S., Boolchand P., Smirniotis P.G.. Surface characterization studies of TiO₂ supported manganese oxide catalysts for low temperature SCR of NO with NH3 . Appl. Catal. B. 2007. 76(1): 123.

42. Derylo-Marczewska A., Gac W., Popivnyak N., Zukocinski G., Pasieczna S. The influence of preparation method on the structure and redox properties of mesoporous Mn-MCM-41 materials. Catal. Today . 2006. 114(2): 293.

43. Liang S., Teng F., Bulgan G., Zong R., Zhu Y. Effect of phase structure of MnO2 nanorod catalyst on the activity for CO oxidation. J. Phys. Chem. C . 2008. 112(14): 5307.

44. Wang. Y., Song Z., Ma D., Luo H., Liang D., Bao X. Characterization of Rh-based catalysts with EPR, TPR, IR and XPS. J. Mol. Catal. A. 1997. 149 (1): 51.

45. Park E., Le H.A., Kim Ye.S., Chin S., Bae G.N., Jurng J. Preparation and characterization of Mn₂O₃/TiO₂ nanomaterials synthesized by combination of СМС and impregnation method with different Mn loading concentration. Mater. Res. Bull. 2012. 47(4): 1040.

46. Tang X., Li J., Suna L, Hao J. Origination of N₂O from NO reduction by NH₃ over β-MnO₂ and α-Mn₂O₃. Appl. Catal. B. 2010. 99: 156.

47. Zou H., Dong X., Lin W. CO selective oxidation in hydrogen-rich gas over copper-series catalysts. J. Natural Gas Chem. 2005. 14 : 29.

48. Chen Ch.-Sh., You Y.-H., Lin J.-H., Chen Yu.-Yu. Effect of highly dispersed active sites of Cu/TiO₂ catalyst on CO oxidation. Catal. Comm . 2008. 9: 2381.

49. Cordoba G., Viniegra M., Fierro J.L.G. TPR, ESR, and XPS study of Cu²⁺ ions in sol-gel–derived TiO₂. J. Solid State Chem . 1998. 138: 1.

50. Li K., Wang Ya., Wang Sh. A comparative study of CuO/TiO₂-SnO₂, CuO/TiO₂ , and CuO/SnO₂ for methanol dehydrogenation. J. Natural Gas Chem. 2009. 18: 1.

51. Rong Zh., Yuhan S., Shaoyi P. Comparative study of Cu/TiO₂ and Cu/ZrO₂ for methanol dehydrogenation. J. Natural Gas Chem . 2000. 9: 110.

52. Coloma F., Marquez F., Rochester C.H., Anderson J.A. Determination of the nature and reactivity of copper sites in Cu-TiO₂ catalysts. Phys. Chem. Chem. Phys . 2000. 2: 5320.

53. Guerreiro E.D., Gorriz O.F., Rivarola J.B., Arrua L.A. Characterization of Cu/SiO₂ catalysts prepared by ion exchange for methanol dehydrogenation. Appl. Catal. A . 1997. 165: 259.

54. Urquieta-Gonzalez E.A., Martins L., Peguin R.P.S., Batista M.S. Identification of extra-framework species on Fe/ZSM-5 and Cu/ZSM-5 catalysts typical microporous molecular sieves with zeolitic structure. Mater. Res . 2002. 5: 321.