Peeling of Magneto-responsive Beams with Large Deformation Mediated by the Parallel Magnetic Field

Elasto-capillarity phenomena are prevalent in various industrial fields such as mechanical engineering,material science,aerospace,soft robotics,and biomedicine.In this study,two typical peeling processes of slender beams driven by the parallel magnetic field are investigated based on experimental and theoretical analysis.The first is the adhesion of two parallel beams,and the second is the self-folding of a long beam.In these two cases,the energy variation method on the elastica is used,and then,the governing equations and transversality boundary conditions are derived.It is shown that the analytical solutions are in excellent agreement with the experimental data.The effects of magnetic induction intensity,distance,and surface tension on the deflection curve and peeling length of the elastica are fully discussed.The results are instrumental in accurately regulating elasto-capillarity in structures and provide insights for the engineering design of programmable microstructures on surfaces,microsensors,and bionic robots.

Biomedical applications of magneto-responsive scaffolds

Stimuli-responsive biomaterials, capable of responding on-demand to changes in their local environment, have become a subject of interest in the field of regenerative medicine. Magneto-responsive biomaterials, which can be manipulated spatiotemporally via an external magnetic field, have emerged as promising candidates as active scaffolds for advanced drug delivery and tissue regeneration applications. These specialized biomaterials can be synthesized by physically and/or chemically incorporating magnetic nanoparticles into the biomaterial structure. However, despite their promising impact on the future of regenerative medicine, magneto-responsive biomaterials still have several limitations that need to be overcome before they can be implemented clinically in a reliable manner, as predicting their behavior and biocompatibility remains an ongoing challenge. This review article will focus on discussing the current fabrication methods used to synthesize magneto-responsive materials, efforts to predict and characterize magneto-responsive biomaterial behavior, and the application of magneto-responsive biomaterials as controlled drug delivery systems, tissue engineering scaffolds, and artificial muscles.

Magnetic-field-driven reverse martensitic transformation with multiple magneto-responsive effects by manipulating magnetic ordering in Fe-doped Co-V-Ga Heusler alloys

Nowadays,searching for the materials with multiple magneto-functional properties and good mechanical properties is vital in various fields,such as solid-state refrigeration,magnetic actuators,magnetic sensors and intelligent/smart devices.In this work,the magnetic-field-induced metamagnetic reverse martensitic transformation(MFIRMT)from paramagnetic martensite to ferromagnetic austenite with multiple magneto-responsive effects is realized in Fe-doped Co-V-Ga Heusler alloys by manipulating the magnetic ordering.The martensitic transformation temperature Tmreduces quasi-linearly with increasing Fe-content.In strikingly contrast with the Fe-free alloys,the magnetization difference(M')across martensitic transformation increases by three orders of magnitude for Fe-doped alloys.The increased M'should be ascribed to the reduction of Tm,almost unchanged Curie temperature of austenite and the increased magnetic moment in the samples with higher Fe-content.The large M'provides strong driving force to realize the MFIRMT and accordingly multiple magneto-responsive effects,such as magnetocaloric,magnetoresistance and magnetostriction effects.Meanwhile,giant Vickers hardness of 518 HV and compressive strength of 1423 MPa are achieved.Multiple magneto-responsive effects with exceptional mechanical properties make these alloys great potential candidates for applications in many fields.