摘要
In this study, micromagnetism simulation by using timte dltterence method is cameo out on the Ncl21-el415/a-Fe nanocomposite magnet with soft phase imbedded in hard phase. The effects of soft magnetic phase size (S) on the magnetic properties and magnetic reversal modes are systematically analyzed. As S increases from 1 nm to 48 nm, the remanence (Jr) increases, while the coercivity (Hci) decreases, leading to the result that the magnetic energy prod- uct [(BH)max] first increases slowly, and then decreases rapidly, peaking at S = 24 nm with the (BH)max of 72.9 MGOe (1 MGOe = 7.95775 kJ.m-3). Besides, with the increase of S, the coercivity mechanism of the nanocomposite magnet changes from nucleation to pinning. Furthermore, by observing the magnetic moment evolution in demagnetization pro- cess, the magnetic reversal of the soft phase in the nanocomposite magnet can be divided into three modes with the increase of S: coherent rotation (S 〈 3 nm), quasi-coherent rotation (3 nm≤S 〈 36 nm), and the vortex-like rotation (S ≥36 nm).
In this study, micromagnetism simulation by using timte dltterence method is cameo out on the Ncl21-el415/a-Fe nanocomposite magnet with soft phase imbedded in hard phase. The effects of soft magnetic phase size (S) on the magnetic properties and magnetic reversal modes are systematically analyzed. As S increases from 1 nm to 48 nm, the remanence (Jr) increases, while the coercivity (Hci) decreases, leading to the result that the magnetic energy prod- uct [(BH)max] first increases slowly, and then decreases rapidly, peaking at S = 24 nm with the (BH)max of 72.9 MGOe (1 MGOe = 7.95775 kJ.m-3). Besides, with the increase of S, the coercivity mechanism of the nanocomposite magnet changes from nucleation to pinning. Furthermore, by observing the magnetic moment evolution in demagnetization pro- cess, the magnetic reversal of the soft phase in the nanocomposite magnet can be divided into three modes with the increase of S: coherent rotation (S 〈 3 nm), quasi-coherent rotation (3 nm≤S 〈 36 nm), and the vortex-like rotation (S ≥36 nm).
基金
Project supported by the Key Program of the National Natural Science Foundation of China(Grant No.51331003)
the International S&T Cooperation Program of China(Grant No.2015DFG52020)
the General Program of Science and Technology Development Project of Beijing Municipal Education Commission,China(Grant No.KM201710005006)
the State Key Laboratory of Advanced Metals and Materials,China(Grant No.2015-ZD02)
