Comparison study on surface depth distribution of chemical species of different nanocomposite Ti–Si binary oxides

[1] Fujishima A(1972)Electrochemcal photolysis of water at a semiconductor electrode Nature 238 37-38

[2] Honda K(2011)A surface science perspective on TiO Surf Sci Rep 66 185-297

[3] Henderson MA(2006) photocatalysis Catal Today 116 99-110

[4] Notari B(2013)Which sites are the active sites in TiO Appl Catal A Gen 451 192-206

[5] Willey RJ(2011)–SiO Prog Org Coat 72 453-460

[6] Panizza M(1986) mixed oxides? J Phys Chem 90 1633-1636

[7] Busca G(2012)Mesoporous mixed oxide catalysts via non-hydrolytic sol–gel: a review Chem Eng J 183 381-386

[8] Debecker DP(2012)Synthesis, Characterization and enhanced photocatalytic activity of TiO J Hazard Mater 229–230 307-320

[9] Hulea V(2009)/SiO J Hazard Mater 161 1281-1287

[10] Mutin PH(2011) nanocomposite in an aqueous solution and acrylic-based coatings Appl Catal A Gen 393 359-366

[1] Fujishima A(1972)Electrochemcal photolysis of water at a semiconductor electrode Nature 238 37-38

[2] Honda K(2011)A surface science perspective on TiO Surf Sci Rep 66 185-297

[3] Henderson MA(2006) photocatalysis Catal Today 116 99-110

[4] Notari B(2013)Which sites are the active sites in TiO Appl Catal A Gen 451 192-206

[5] Willey RJ(2011)–SiO Prog Org Coat 72 453-460

[6] Panizza M(1986) mixed oxides? J Phys Chem 90 1633-1636

[7] Busca G(2012)Mesoporous mixed oxide catalysts via non-hydrolytic sol–gel: a review Chem Eng J 183 381-386

[8] Debecker DP(2012)Synthesis, Characterization and enhanced photocatalytic activity of TiO J Hazard Mater 229–230 307-320

[9] Hulea V(2009)/SiO J Hazard Mater 161 1281-1287

[10] Mutin PH(2011) nanocomposite in an aqueous solution and acrylic-based coatings Appl Catal A Gen 393 359-366