Affiliation:
1. Department of Applied Physics National Pingtung University No. 4–18 Minsheng Rd. Pingtung 90003 Taiwan
2. Robinson Research Institute Victoria University of Wellington P.O. Box 33–436 Lower Hutt 5046 New Zealand
3. The MacDiarmid Institute for Advanced Materials and Nanotechnology Wellington 6011 New Zealand
Abstract
AbstractThis research demonstrates dynamic control of the magneto‐optical properties in Tm3Fe5O12 (TmIG)/Pt by employing electrical current modulation, particularly within the UV spectrum. Notably, manipulation of circular dichroism (CD) is achieved in perpendicularly magnetized TmIG without an external magnetic field. Furthermore, by carefully managing the magnetization behavior of TmIG through low current control and introducing a moderate external magnetic field, the reversible inversion of the CD signal in TmIG is successfully demonstrated, offering nonvolatile control. It is proposed that the change in CD signal arises from the temperature gradient induced by Joule heating, resulting in a spin current flowing across the TmIG. Moreover, the theoretical framework confirms that spin alignment transitions occur between O(2p) and Fe(3d), as well as between O(2p) and Tm(5d), under the influence of the Tm(4f) moment. This leads to a transition from a collinear to a noncollinear spin configuration, effectively suppressing pd Laporte‐selected relaxation within TmIG. This discovery opens the path for the development of dynamic, large‐area, and ultrathin chiral optical devices using magnetic insulators.
Funder
National Science and Technology Council