A comparative study of a direct and pulse electrodeposition method of TiO2 films and its effect on photoelectrocatalytic degradation of methyl orange dye

Larbi Khadidja Hadj; Habelhames Farid; Lakhdari Meriem; Bennabi Farid; Nessark Belkacem; Adjdir Mehdi; Nebatti Abdelkader Echchergui; Amrani Bouhalouane

doi:10.1007/s11801-021-0193-4

[1] Scarpelli F., Mastropietro T., Poerio T. and Godbert N., Mesoporous TiO2 Thin Films: State of the Art, Titanium Dioxide-Material for a Sustainable Environment, 57 (2018).

[2] Teferi B., Schnupf U., Manseki K., Sugiura T. and Vafaei S., Synthesis and Deposition of Rutile TiO2 for Dye-Sensitized Solar Cell Applications, In ASME International Mechanical Engineering Congress and Exposition, American Society of Mechanical Engineers, V006T006A093 (2019).

[3] Zhang Y., Chen J., Hou G., Li D., Wu Y., Xu J., Xu L. and Chen K., Optics Express 28, 6064 (2020).

[4] Woods R., Searle J., Pursglove A. and Worsley D., Journal of Environmental Chemical Engineering 7, 103336 (2019).

[5] Rzaij J.M. and Abass A.M., Journal of Chemical Reviews 2, 114 (2020).

[6] Nebatti A., Pflitsch C., Eckert C. and Atakan B., Progress in Organic Coatings 67, 356 (2010).

[7] Fujishima A., Rao T.N. and Tryk D.A., Journal of Photochemistry and Photobiology C: Photochemistry Reviews 1, 1 (2000).

[8] Hoffmann M.R., Martin S.T., Choi W. and Bahnemann D.W., Chemical Reviews 95, 69 (1995).

[9] Cherrak R., Hadjel M., Benderdouche N., Adjdir M., Mokhtar A., Khaldi K., Sghier A. and Weidler P.G., Silicon 12, 927 (2019).

[10] Tong H., Ouyang S., Bi Y., Umezawa N., Oshikiri M. and Ye J., Advanced Materials 24, 229 (2012).

[11] Zhao W., Bai Z., Ren A., Guo B. and Wu C., Applied Surface Science 256, 3493 (2010).

[12] Seong S.G., Kim E.J., Kim Y.S., Lee K.E. and Hahn S.H., Applied Surface Science 256, 1 (2009).

[13] Haider A.J., AL-Anbari R.H., Kadhim G.R. and Salame C.T., Energy Procedia 119, 332 (2017).

[14] Li J.-G., Ikeda M., Tang C., Moriyoshi Y., Hamanaka H. and Ishigaki T., The Journal of Physical Chemistry C 111, 18018 (2007).

[15] Di Paola A., Bellardita M. and Palmisano L., Catalysts 3, 36 (2013).

[16] Rasheed M. and Barillé R., Journal of Non-Crystalline Solids 476, 1 (2017).

[17] Abou-Helal M. and Seeber W., Applied Surface Science 195, 53 (2002).

[18] Chen Z., Dündar I., Acik I.O. and Mere A., In IOP Conference Series: Materials Science and Engineering 503, 012006 (2019).

[19] Shinde V., Gujar T. and Lokhande C., Sensors and Actuators B: Chemical 120, 551 (2007).

[20] Meng L., Wang Z., Yang L., Ren W., Liu W., Zhang Z., Yang T. and Dos Santos M., Applied Surface Science 474, 211 (2019).

[21] Safranek W.H., The Properties of Electrodeposited Metals and Alloys: a Handbook, American Electroplaters and Surface Finishers Society, 1986.

[22] Aliofkhazraei M. and Makhlouf A.S.H., Hand-book of Nanoelectrochemistry: Electrochemical Synthesis Methods, Properties, and Characteriz-ation Techniques, Springer, 2016.

[23] El Moursli F.C., Douayar A., Hajji F., Nouneh K., Guessous A., Nabih K., Hadri A. and Abd-Lefdil M., Sensors & Transducers 27, 137 (2014).

[24] Wang H., Song Y., Liu W., Yao S. and Zhang W., Materials Letters 93, 319 (2013).

[25] Gal D., Hodes G., Lincot D. and Schock H.-W., Thin Solid Films 361, 79 (2000).

[26] Khan R., Hassan M.S., Jang L.-W., Yun J.H., Ahn H.- K., Khil M.-S. and Lee I.-H., Ceramics International 40, 14827 (2014).

[27] Lajevardi S. and Shahrabi T., Applied Surface Science 256, 6775 (2010).

[28] Wu M.-S., Ceng Z.-Z. and Chen C.-Y., Electro-chimica Acta 191, 256 (2016).

[29] Gyftou P., Pavlatou E. and Spyrellis N., Applied Surface Science 254, 5910 (2008).

[30] An H.-J., Jang S.-R., Vittal R., Lee J. and Kim K.-J., Electrochimica Acta 50, 2713 (2005).

[31] Hosono E., Fujihara S., Kakiuchi K. and Imai H., Journal of the American Chemical Society 126, 7790 (2004).

[32] Alexander L. and Klug H.P., Journal of Applied Physics 21, 137 (1950).

[33] Thompson C.V., Annual Review of Materials Science 30, 159 (2000).

[34] Najim J. and Rozaiq J., International Letters of Chemistry, Physics and Astronomy 10, 137 (2013).

[35] Sarkar A., Ghosh S., Chaudhuri S. and Pal A., Thin Solid Films 204, 255 (1991).

[36] Chakraborty P., Datta G. and Ghatak K., Physica B: Condensed Matter 339, 198 (2003).

[37] Samanta P., Saha A. and Kamilya T., Chemical Synthesis and Optical Properties of ZnO Nanoparticles, Журнал нано-та електронно? ф?зики, 04015-04011- 04015-04012, 2014.

[38] Juma A.O., Acik I.O., Mikli V., Mere A. and Krunks M., Thin Solid Films 594, 287 (2015).

[39] Ghosh S. and Basu R.N., Nanoscale Characterization, In Noble Metal-Metal Oxide Hybrid Nanoparticles, Elsevier, 65 (2019).

[40] Fathy N. and Ichimura M., Journal of Crystal Growth 294, 191 (2006).

[41] Frade T., Lobato K., Carreira J.F., Rodrigues J., Monteiro T. and Gomes A., Materials & Design 110, 18 (2016).

[42] Nezamzadeh-Ejhieh A. and Moazzeni N., Journal of Industrial and Engineering Chemistry 19, 1433 (2013).

[43] Lee K.M., Lai C.W., Ngai K.S. and Juan J.C., Water Research 88, 428 (2016).

[44] Kou J., Lu C., Wang J., Chen Y., Xu Z. and Varma R.S., Chemical Reviews 117, 1445 (2017).

[45] Lakhdari M. and Habelhames F., Journal of Materials Science: Materials in Electronics 30, 6107 (2019).

[46] Ahmed S., Rasul M., Brown R. and Hashib M., Journal of Environmental Management 92, 311 (2011).

[47] Leelavathi A., Madras G. and Ravishankar N., Physical Chemistry Chemical Physics 15, 10795 (2013).

[48] Lakhdari M., Habelhames F., Nessark B., Girtan M., Derbal-Habak H., Bonnassieux Y., Tondelier D. and Nunzi J.M., The European Physical Journal Applied Physics 84, 30102 (2018).