Photo-controlled exchange bias in CoO@Co-Fe PBA core-shell heterostructures

Regulating the exchange bias (EB) effect via an external field allows one to effectively tailor the properties of spin-valve-based spintronic devices. However, as a reliable way to manipulate the magnetic properties of materials, there have been few reports on the effect of light irradiation on the EB effect so far. In this work, a non-volatile light-tunable EB effect is achieved in a well-designed CoO and CoFe Prussian blue analogue core-shell structure (CoO@Co-Fe PBA), where the antiferromagnetic CoO has a large anisotropy, and the molecular magnet Co-Fe PBA is photosensitive. The EB field of this hybrid can be reduced by similar to 50% after irradiation for 20 minutes, and the photo-induced change can be further increased by extending the irradiation time. In addition, the switching of the two EB effect states can be successfully implemented by switching red and blue light irradiation. Herein, this interesting photo-controlled EB effect is attributed to the change in the magnetization of the photosensitive Co-Fe PBA shell after light radiation, and the change is achieved by manipulating the number of Fe-III-Co-II magnetic pairs in the shell by incident light. Apparently, this striking light-controlled EB effect opens up new prospects for the design of new-generation optoelectronic devices.

Automated summary

In this study, researchers achieved a non-volatile light-tunable exchange bias effect in a well-designed core-shell structure of CoO and CoFe Prussian blue analogue. The exchange bias field of the hybrid can be reduced after irradiation and further increased by extending the irradiation time. Additionally, switching between two exchange bias effect states was successfully implemented by switching red and blue light irradiation.