Ferromagnetic Instability in a Doped Band-Gap Semiconductor FeGa3

Abstract

We report the effects of electron doping on the ground state of a diamagnetic semiconductor FeGa3 with a band gap of 0.5 eV. By means of electrical resistivity, magnetization and specific heat measurements we have found that gradual substitution of Ge for Ga in FeGa3-yGey yields metallic conduction at a very small level of y = 0.006, then induces weak ferromagnetic (FM) order at y = 0.13 with a spontaneous moment of 0.1 μB/Fe and a Curie temperature TC= 3.3 K, which continues increasing to TC = 75 K as doping reaches y = 0.41. The emergence of the FM state is accompanied by quantum critical behavior as observed in the specific heat, C/T -lnT, and in the magnetic susceptibility, M/B T-4/3. At y= 0.09, the specific heat divided by temperature C/T reaches a large value of 70 mJ/K2molFe, twice as large as that reported on FeSi1-xGex for xc= 0.37 and Fe1-xCoxSb2 for xc=0.3 at their respective FM quantum critical points. The critical concentration yc=0.13 in FeGa3-yGey is quite small, despite the fact that its band gap is one order of magnitude larger than those in FeSi and FeSb2. In contrast, no FM state emerges by substituting Co for Fe in Fe1-xCoxGa3 in the whole range 0 ≤ x ≤ 1, although both types of substitution should dope electrons into FeGa3. The FM instability found in FeGa3-yGey indicates that strong electron correlations are induced by the disturbance of the Fe 3d - Ga 4p hybridization.