中文摘要：

实验研究了磁感应强度和冷却速率对Tb（0.27）Dy（0.73）Fe（1.95）合金凝固过程中（Tb,Dy）Fe2相取向行为及合金磁性能的影响.结果表明,将强磁场作用于Tb（0.27）Dy（0.73）Fe（1.95）合金的凝固过程可以制备出（Tb,Dy）Fe2相沿取向的组织,同时显著提高了合金的磁致伸缩性能;通过提高磁感应强度可以在更快的冷却速率下得到取向的组织;在4-10 T范围内,随着冷却速率的增加,（Tb,Dy）Fe2相沿取向所需的磁感应强度增加,而发生（110）取向的磁感应强度减小.随着冷却速率的增加,合金的饱和磁化强度增加,而强磁场的施加对合金饱和磁化强度的变化没有明显影响.（Tb,Dy）Fe2相的取向行为受＊Tb,Dy）Fe3相取向行为的影响,且由磁晶各向异性能与磁场作用时间共同控制.

英文摘要：

The rare-earth giant magnetostrictive material Tb（0.27）Dy（0.73）Fe（1.95） is one of the most important functional magnetic materials.Their superior properties include high saturation magnetostrictive coefficient at room temperature,high electromechanical coupling coefficients,high output power,fast response,high energy density,and non-contact drive.Thus,they can be used to build sensors,precision machinery,magnetomechanical transducers,and adaptive vibrationcontrol systems.In this material,the magnetic phase（Tb,Dy）Fe2 has a typical MgCu2-type cubic Laves phase structure and exhibits different magnetostrictive properties along different crystal orientations.The 111 direction of this phase is the easy magnetization axis,along which the linear magnetostriction is higher than other directions.Thus,researchers have focused on preparing（Tb,Dy）Fe2 with a crystallographic orientation along or close to the 111 direction.Generally,the directional solidification method is used to prepare the Tb（0.27）Dy（0.73）Fe（1.95） alloy.However,a crystal orientated along the 110 or 112 direction is always obtained and both of these directions require a high external magnetic field for improved magnetostrictive performance.The 111 preferred growth orientation can be acquired using seed crystal technology.However,the relatively low growth velocity can cause the appearance of the linear（Tb,Dy）Fe3 phase which induces a high brittleness of the material.Therefore,new methods to prepare Tb（0.27）Dy（0.73）Fe（1.95） products with high111 orientation at higher growth velocity are required.In this paper,we solidify the Tb（0.27）Dy（0.73）Fe（1.95） alloys under various high magnetic field and cooling rate conditions.We study the effects of the magnetic flux density and cooling rate on the crystal orientation of the（Tb,Dy）Fe2 phase and the magnetization behavior of the alloys.It is found that after field-treated solidification,a high 111 orientation of（Tb,Dy）Fe2 along the magnetic field direct