Increased room temperature ferromagnetism in Co-doped tetrahedral perovskite niobates

Dilute magnetic semiconductors (DMSs), such as (In, Mn)As and (Ga, Mn)As prototypes, are limited to III-V semiconductors with Curie temperatures (T-c) far from room temperature, thereby hindering their wide application. Here, one kind of DMS based on perovskite niobates is reported. BaMxNb(1-x)O3-delta (M = Fe, Co) powders are prepared by the composite-hydroxide-mediated method. The addition of M elements endows BaMxNb(1-x)O3-delta with local ferromagnetism. The tetragonal BaCoxNb(1-x)O3-delta nanocrystals can be obtained by Co doping, which shows strong saturation magnetization (M-sat) of 2.22 emu g(-1), a remnant magnetization (M-r) of 0.084 emu g(-1) and a small coercive field (H-c) of 167.02 Oe at room temperature. The ab initio calculations indicate that Co doping could lead to a 64% local spin polarization at the Fermi level (E-F) with net spin DOS of 0.89 electrons eV(-1), this result shows the possibility of maintaining strong ferromagnetism at room temperature. In addition, the trade-off effect between the defect band absorption and ferromagnetic properties of BaMxNb(1-x)O3-delta is verified experimentally and theoretically.

Automated summary

A dilute magnetic semiconductor based on perovskite niobates has been reported, showing stable local ferromagnetism at room temperature with the addition of Co doping. The material exhibits strong saturation magnetization, remnant magnetization, and small coercive field, indicating potential for practical applications.