Alloys with large solidification intervals are prone to issues from the disordered growth and defect for-mation;accordingly,finding ways to effectively optimize the microstructure,further to improve the mechanical properties is of great importance.To this end,we couple travelling magnetic fields with sequential solidification to continuously regulate the mushy zones of Al-Cu-based alloys with large solid-ification intervals.Moreover,we combine experiments with simulations to comprehensively analyze the mechanisms on the optimization of microstructure and properties.Our results indicate that only down-ward travelling magnetic fields coupled with sequential solidification can obtain the refined and uniform microstructure,and promote the growth of matrix phase α-Al along the direction of temperature gradient.Additionally,the secondary dendrites and precipitates are reduced,while the solute partition coefficient and solute solid-solubility are raised.Ultimately,downward travelling magnetic fields can increase the ultimate tensile strength,yield strength,elongation and hardness from 196.2 MPa,101.2 MPa,14.5％ and 85.1 kg mm-2 without travelling magnetic fields to 224.1 MPa,114.5 MPa,17.1％ and 102.1 kg mm-2,and improve the ductility of alloys.However,upward travelling magnetic fields have the adverse effects on microstructural evolution,and lead to a reduction in the performance and ductility.Our findings demonstrate that long-range directional circular flows generated by travelling magnetic fields direction-ally alter the transformation and redistribution of solutes and temperature,which finally influences the solidification behavior and performance.Overall,our research present not only an innovative method to optimize the microstructures and mechanical properties for alloys with large solidification intervals,but also a detailed mechanism of travelling magnetic fields on this optimization during the sequential solidification.