TY - JOUR
T1 - Effects of Nearly-2D Oxygen Vacancy Clustering on the Magnetic Properties of d0 Systems: The Case of Anatase and Rutile TiO2
AU - Drera, Giovanni
AU - Mozzati, Maria C.
AU - Malavasi, Lorenzo
AU - Galinetto, Pietro
AU - Sangaletti, Luigi Ermenegildo
PY - 2018
Y1 - 2018
N2 - A comprehensive magnetic characterization in a set of rutile and anatase thin films grown on different substrates is reported. TiO2−δ films have been grown with the RF-sputtering technique on various non-magnetic substrates (fused silica, Al2O3, LSAT); subsequently, a protocol of annealing procedures has been applied in order to alter the sample oxygen stoichiometry. Magnetic characterization has been carried out at each step of the films treatments. It is shown that control over oxygen stoichiometry can be used in these samples to induce room-temperature ferromagnetism (FM). Percolation schemes developed for the anatase or rutile lattices are considered to show that FM is related to clustered oxygen vacancies. The values of saturation magnetization, determined from thin films in a wide thickness range (33–317 nm), indicate that ferromagnetic ordering can be explained on the basis of a magnetic layer hosting a percolating cluster related to oxygen vacancies at the interface with the substrate or at the film surface, the first being common to all samples, while the second being triggered by vacuum annealing.
AB - A comprehensive magnetic characterization in a set of rutile and anatase thin films grown on different substrates is reported. TiO2−δ films have been grown with the RF-sputtering technique on various non-magnetic substrates (fused silica, Al2O3, LSAT); subsequently, a protocol of annealing procedures has been applied in order to alter the sample oxygen stoichiometry. Magnetic characterization has been carried out at each step of the films treatments. It is shown that control over oxygen stoichiometry can be used in these samples to induce room-temperature ferromagnetism (FM). Percolation schemes developed for the anatase or rutile lattices are considered to show that FM is related to clustered oxygen vacancies. The values of saturation magnetization, determined from thin films in a wide thickness range (33–317 nm), indicate that ferromagnetic ordering can be explained on the basis of a magnetic layer hosting a percolating cluster related to oxygen vacancies at the interface with the substrate or at the film surface, the first being common to all samples, while the second being triggered by vacuum annealing.
KW - Condensed Matter Physics
KW - Electronic, Optical and Magnetic Materials
KW - anatase
KW - ferromagnetism
KW - percolation
KW - rutile
KW - Condensed Matter Physics
KW - Electronic, Optical and Magnetic Materials
KW - anatase
KW - ferromagnetism
KW - percolation
KW - rutile
UR - http://hdl.handle.net/10807/134204
UR - http://onlinelibrary.wiley.com/journal/10.1002/(issn)1521-3951
U2 - 10.1002/pssb.201800058
DO - 10.1002/pssb.201800058
M3 - Article
SN - 0370-1972
VL - 255
SP - 1800058-N/A
JO - PHYSICA STATUS SOLIDI B-BASIC RESEARCH
JF - PHYSICA STATUS SOLIDI B-BASIC RESEARCH
ER -