Over the past two decades,magnetoelectric(ME)materials have garnered growing attention for their unique ability to couple electric and magnetic functions,two fundamental ferroic states,in a bidirectional and energy-ef...Over the past two decades,magnetoelectric(ME)materials have garnered growing attention for their unique ability to couple electric and magnetic functions,two fundamental ferroic states,in a bidirectional and energy-efficient manner[1].This coupling opens up exciting possibilities for next-generation technologies in sensing,memory,energy harvesting,and wearable electronic devices[2].However,engineering high-performance ME nanomaterials remains an enduring challenge,particularly due to the inherent conflicts between ferromagnetism(which typically originates from partially filled d/f orbitals)and ferroelectricity(which generally favors empty d/f orbitals)[3].These intrinsic incompatibilities have presented a historical limit of the effectiveness in single-phase ME materials.展开更多
文摘Over the past two decades,magnetoelectric(ME)materials have garnered growing attention for their unique ability to couple electric and magnetic functions,two fundamental ferroic states,in a bidirectional and energy-efficient manner[1].This coupling opens up exciting possibilities for next-generation technologies in sensing,memory,energy harvesting,and wearable electronic devices[2].However,engineering high-performance ME nanomaterials remains an enduring challenge,particularly due to the inherent conflicts between ferromagnetism(which typically originates from partially filled d/f orbitals)and ferroelectricity(which generally favors empty d/f orbitals)[3].These intrinsic incompatibilities have presented a historical limit of the effectiveness in single-phase ME materials.
