Open AccessMathematical model depicting the deposition kinetics process into rf-magnetron co-sputtering of strontium barium titanate thin films
Author(s) -
J. Reséndiz-Muñoz,
M. T. Zagaceta-Álvarez,
J. L. Fernández-Muñoz,
M. A. Gruintal-Santos
Publication year - 2022
Publication title -
digest journal of nanomaterials and biostructures
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.256
H-Index - 44
ISSN - 1842-3582
DOI - 10.15251/djnb.2022.171.1
Subject(s) - stoichiometry , materials science , thin film , deposition (geology) , kinetics , strontium , sputter deposition , sputtering , analytical chemistry (journal) , mineralogy , chemical engineering , inorganic chemistry , nanotechnology , chemistry , paleontology , physics , organic chemistry , chromatography , quantum mechanics , sediment , engineering , biology
"Thin films deposition kinetics of BaXSr1-XTiO3 (BST)/nichrome is modeled by the stoichiometric rate of a perovskite-type material such as ABO3, where cations A, B, and the anion oxygen should ideally have a 1:1:3 rate, respectively. The experimental stoichiometry data measured by EDS on films of 240 nm, and the Ba/Sr, (Ba+Sr)/Ti rates considered in percentages starting from arithmetic and the sigmoidal relationship between Ba and Sr. They show relationships in sigmoidal, exponential, and parabolic mathematical functions that together describe the BST thin films deposition kinetics by means of RFMagnetron Co-Sputtering (RFMCS). The proposed mathematical model is fundamental to optimize, explain and use the deposition process working conditions, such as the working pressure, the Ar/O2 rate in percentage, and sccm. The controlled applied power on each BaTiO3 (BTO) and SrTiO3 (STO) targets achieve more accurate stoichiometry in thin films deposition for solid solutions on quaternary materials."