图 1  样品FeGa/IrMn/MgO(001)的X射线衍射图　(a) θ-2θ 扫描图; (b) 面内φ扫描图

Fig. 1.  X-ray diffraction measurement for the sample of FeGa/IrMn/MgO(001): (a) θ-2θ scan; (b) in-plane φ-scan.

图 2  (a) FeGa单层膜和(b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $的FeGa/IrMn双层膜在${\varphi }_{H}=$ 0°, 30°, 45°时的代表性铁磁共振微分吸收谱; (c), (d) 相应的共振场$ {H}_{\mathrm{r}} $随${\varphi }_{H}$的变化关系(空心点为实验值, 实线(a), (b)和虚线(c), (d)为拟合曲线)

Fig. 2.  Representative ferromagnetic resonance derivative absorption spectra for (a) FeGa single layer and (b) FeGa/IrMn bilayer with $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $ measured at ${\varphi }_{H}=$ 0°, 30°, 45°; (c), (d) the corresponding resonance field $ {H}_{\mathrm{r}} $ as a function of ${\varphi }_{H}$(Open dots are the experimental data, solid (a), (b) and dashed (c), (d) lines are the theoretical fitting results).

图 3  在不同外磁场方向$ {\varphi }_{H} $下, $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $和$ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right] $的FeGa/IrMn双层膜的典型纵向和横向MOKE磁滞回线(M_s是饱和磁化强度)　(a)$ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=0^\circ; $ (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=30^\circ; $ (c) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}= $ $ 45^\circ; $ (d) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=90^\circ $; (e) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=0^\circ; $ (f) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=35^\circ; $ (g) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=45^\circ; $ (h) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=90^\circ\mathrm{. } $蓝线和红线分别对应于磁滞回线的磁场下行支和磁场上行支; 磁化翻转过程中FeGa自旋方向用箭头表示; 相应的磁化翻转场也标记在图中

Fig. 3.  Typical longitudinal and transverse MOKE loops at different external field orientations $ {\varphi }_{H} $ for the FeGa/IrMn bilayer with $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $ and $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], $M_s is the saturation magnetization: (a) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=0^\circ; $ (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=30^\circ; $ (c)${K}_{\mathrm{e}\mathrm{b}}// $$ \left[100\right],$ $ {\varphi }_{H}= $ $ 45^\circ; $(d) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right], $ $ {\varphi }_{H}=90^\circ $; (e) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=0^\circ; $ (f) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=35^\circ; $ (g) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right], {\varphi }_{H}=45^\circ; $ (h) ${K}_{\mathrm{e}\mathrm{b}}//\left[110\right], $$ {\varphi }_{H}=90^\circ.$ The blue and red curves correspond to the magnetic field descending and ascending branches of hyste-resis loops, respectively; the arrows enclosed by a square represent the orientation of FeGa spins in the magnetic switching routes; the corresponding magnetic switching fields are presented as well.

图 4  FeGa/IrMn双层膜的磁化翻转场随外磁场方向$ {\varphi }_{H} $的变化关系　(a)$ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $; (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right] $(实心和空心点对应于实验值, 实线和虚线对应于拟合曲线)

Fig. 4.  External magnetic field orientation $ {\varphi }_{H} $ dependence of the magnetic switching fields for the FeGa/IrMn bilayers: (a) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $; (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right] $ (The solid and open dots represent experimental values, and the solid and dashed lines represent fitted curves).

图 5  FeGa/IrMn双层膜的磁各向异性能随磁化强度方向的变化关系　(a) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $; (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right] $; (c), (d) 相对应的磁各向异性改变示意图

Fig. 5.  Magnetic anisotropy energy as a function of orientation of magnetization in FeGa/IrMn bilayers: (a) $ {K}_{\mathrm{e}\mathrm{b}}//\left[100\right] $; (b) $ {K}_{\mathrm{e}\mathrm{b}}//\left[110\right] $; (c), (d) corresponding schematic diagram of magnetic anisotropy change.