Abstract

Transition metals such as Mn generally have large local moments in covalent semiconductors due to their partially filled $d$ shells. However, Mn magnetization in group-IV semiconductors is more complicated than often recognized. Here we report a striking crossover from a quenched Mn moment $(<0.1{\ensuremath{\mu}}_{B})$ in amorphous Si $(a\text{-Si})$ to a large distinct local Mn moment $(\ensuremath{\ge}3{\ensuremath{\mu}}_{B})$ in amorphous Ge $(a\text{-Ge})$ over a wide range of Mn concentrations (0.005--0.20). Corresponding differences are observed in $d$-shell electronic structure and the sign of the Hall effect. Density-functional-theory calculations show distinct local structures, consistent with different atomic density measured for $a\text{-Si}$ and $a\text{-Ge}$, respectively, and the Mn coordination number ${N}_{c}$ is found to be the key factor. Despite the amorphous structure, Mn in $a\text{-Si}$ is in a relatively well-defined high coordination interstitial type site with broadened $d$ bands, low moment, and electron ($n$-type) carriers, while Mn in $a\text{-Ge}$ is in a low coordination substitutional type site with large local moment and holes ($p$-type) carriers. Moreover, the correlation between ${N}_{c}$ and the magnitude of the local moment is essentially independent of the matrix; the local Mn moments approach zero when ${N}_{c}>7$ for both $a\text{-Si}$ and $a\text{-Ge}$.

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