When coupled with ferromagnetic layers (FM), topological insulators (TI) are expected to boost the charge-to-spin conversion efficiency across the FM/TI interface. In this context, a thorough control and optimization of the FM/TI interface quality are requested. Here, the evolution of the chemical, structural, and magnetic properties of the Fe/Sb(2)Te(3)heterostructure is presented as a function of a rapid mild thermal annealing conducted on the Sb2Te3-TI (up to 200 degrees C). While the bilayer is not subjected to any thermal treatment upon Fe deposition, the annealing of Sb(2)Te(3)markedly improves its crystalline quality, leading to an increase in the fraction of ferromagnetic Fe atoms at the buried Fe/Sb(2)Te(3)interface and a slight lowering of the magnetic coercivity of the Fe layer. The method is an efficient tool to clean up the Fe/Sb(2)Te(3)interface, which may be extended to different FM/TI heterostructures. Simultaneously to the interface reconstruction, a constant approximate to 20% fraction of FeTe develops at the interface. Since FeTe can display superconductivity, the Fe/Sb(2)Te(3)system could have potentialities for exploiting phenomena at the edge of magnetism, superconductivity and topology.
Fe/Sb(2)Te(3)Interface Reconstruction through Mild Thermal Annealing
Longo Emanuele;Wiemer Claudia;Cecchini Raimondo;Longo Massimo;Lamperti Alessio;Fanciulli Marco;Mantovan Roberto
2020
Abstract
When coupled with ferromagnetic layers (FM), topological insulators (TI) are expected to boost the charge-to-spin conversion efficiency across the FM/TI interface. In this context, a thorough control and optimization of the FM/TI interface quality are requested. Here, the evolution of the chemical, structural, and magnetic properties of the Fe/Sb(2)Te(3)heterostructure is presented as a function of a rapid mild thermal annealing conducted on the Sb2Te3-TI (up to 200 degrees C). While the bilayer is not subjected to any thermal treatment upon Fe deposition, the annealing of Sb(2)Te(3)markedly improves its crystalline quality, leading to an increase in the fraction of ferromagnetic Fe atoms at the buried Fe/Sb(2)Te(3)interface and a slight lowering of the magnetic coercivity of the Fe layer. The method is an efficient tool to clean up the Fe/Sb(2)Te(3)interface, which may be extended to different FM/TI heterostructures. Simultaneously to the interface reconstruction, a constant approximate to 20% fraction of FeTe develops at the interface. Since FeTe can display superconductivity, the Fe/Sb(2)Te(3)system could have potentialities for exploiting phenomena at the edge of magnetism, superconductivity and topology.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.