Cooperative control of perpendicular magnetic anisotropy via crystal structure and orientation in single-crystal flexible SrRuO3 membranes

TL;DR

This paper presents a new method to synthesize flexible, single-crystal SrRuO3 membranes with tunable perpendicular magnetic anisotropy, enabling advances in flexible spintronic devices through crystal structure and orientation control.

Contribution

It introduces a facile water-soluble sacrificial layer technique for fabricating flexible SrRuO3 membranes with controllable magnetic anisotropy based on crystal engineering.

Findings

Achieved highly tunable magnetic anisotropy from in-plane to out-of-plane.

Demonstrated PMA energy of 7.34×10^6 erg/cm^3.

Maintained magnetic stability after 10,000 bending cycles.

Abstract

Flexible magnetic materials with robust and controllable perpendicular magnetic anisotropy (PMA) are highly desirable for developing flexible high-performance spintronic devices. However, it is still challenge to fabricate PMA films through current techniques of direct deposition on polymers. Here, we report a facile method for synthesizing single-crystal freestanding SrRuO3 (SRO) membranes with controlled crystal structure and orientation using water-soluble Ca3-xSrxAl2O6 sacrificial layers. Through cooperative effect of crystal structure and orientation engineering, flexible SrRuO3 membranes reveal highly tunable magnetic anisotropy from in-plane to our-of-plane with a remarkable PMA energy of 7.34*106 erg/cm3. Based on the first-principles calculations, it reveals that the underlying mechanism of PMA modulation is intimately correlated with structure-controlled Ru 4d-orbital occupation, as well as the spin-orbital matrix element differences, dependent on the crystal orientation. In addition, there are no obvious changes of the magnetism after 10,000 bending cycles, indicating an excellent magnetism reliability in the prepared films. This work provides a feasible approach to prepare the flexible oxide films with strong and controllable PMA.