Ion implantation effects on the microstructure, electrical resistivity and thermal conductivity of amorphous CrSi2 thin films

The microstructural changes induced by ion implantation may lead to advantageous modifications of chromium disilicide's (CrSi2) electrical and thermal properties. As a potential thermoelectric material, CrSi2 has attracted attention due to its semiconductor properties and high thermal stability. This contribution investigates the influence of different ion species and implantation conditions on the microstructure, electrical resistivity rho and thermal conductivity kappa behaviors in amorphous CrSi2 thin films. 260-nm-thick CrSi2 films were produced by magnetron sputtering and deposited onto a SiO2/Si substrate. Samples were implanted at room temperature either with Ne or Al ions to form a concentration-depth plateau reaching a concentration of approximate to 1.0 at.% (Ne), or approximate to 0.008 at.% (Al). Ne and Al implantations were also performed with the targets heated at 250 degrees C. The microstructural modifications were characterized via TEM and STEM-EDX. The electrical resistivity rho was measured by the van der Pauw method, and the thermal conductivity kappa measurements were obtained with SThM. The results obtained show that room temperature Al and Ne implantations cause the reduction of rho as compared to the pristine film. In contrast, the rho values are significantly higher for Ne and Al implantations in heated substrates. The microstructure evolution, electrical and thermal behaviors are discussed considering the effects of radiation damage and the formation of dense nanocrystallite arrays during the implantation process.

Automated summary

The microstructural changes induced by ion implantation have significant effects on the electrical and thermal properties of chromium disilicide (CrSi2). This study investigates the influence of different ion species and implantation conditions on the microstructure, electrical resistivity, and thermal conductivity of amorphous CrSi2 thin films.