磁浮子是一种类磁斯格明子的新型表面型三维拓扑磁结构，其和磁斯格明子共同应用与自旋电子学器件，能够有效的阻止有限温下磁斯格明子漂移运动，从而保证器件稳定性。本项目拟通过微磁学计算模拟，针对螺旋磁材料，系统性的开展基于磁浮子和磁斯格明子的自旋电子学器件原理性应用研究。项目将通过深入研究两种磁结构动力学过程，获得纳米器件结构、温度、磁场及电流驱动对磁浮子生成、两种磁结构间的转换、稳定输运过程的影响及其物理规律，并探索两种磁结构的探测手段。项目的实施将为基于磁浮子和磁斯格明子的自旋电子学器件构筑提供重要的理论依据。

Magnetic chiral bobber, a Skyrmion like 3D topological magnetic structure, can be applied in future spintronics device together with Skyrmions, to improve the stability of device by preventing the Skyrmion shift in finite temperature. In this project, by micro magnetics simulation, we attempt to study the spintronics application of Magnetic chiral bobber and Magnetic Skyrmion in chiral magnet. With the detailed studies of dynamics of both two magnetic structure, the effect and the physics of structure of device, temperature, magnetic field and applied electronic current on the creation of magnetic chiral bobber, steady transformation and transition of the two magnetic structures will be obtained. Meanwhile, the Detection method of two structures will be explored. The proposed work is expected to provide chance of exploring future spintronics devices based on magnetic chiral bobber and magnetic Skyrmion.