Topology-induced chiral photon emission from a large-scale meron lattice

• Published in: Nature electronics Vol. 6; no. 7; pp. 516 - 524
• Main Authors: Wu, Xuefeng, Li, Xu, Kang, Wenyu, Zhang, Xichao, Chen, Li, Zhong, Zhibai, Zhou, Yan, Åkerman, Johan, Wu, Yaping, Zhang, Rong, Kang, Junyong
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 01.07.2023
• Subjects: 639/301/119; 639/624/1020; 639/766/1130; 639/766/119/1001; Electrical Engineering; Engineering
• ISSN: 2520-1131
• DOI: 10.1038/s41928-023-00990-4

Merons are a class of topologically protected particle-like structures created in in-plane magnetized magnetic films. The structures can act as information carriers and could be used for magnetic storage. However, the development of such applications is hampered by limitations in the size, thermal stability and magnetic-field requirements of the systems. Here we report the construction of millimetre-scale meron lattices that are stable at room temperature and under zero magnetic field. Our system is based on a trilayer structure composed of a thin iron film sandwiched between films of palladium and magnesium oxide (Pd/Fe/MgO) on a gallium nitride wafer. It is fabricated using a molecular-beam epitaxy approach that is assisted by a high magnetic field, which leads to a strong Dzyaloshinskii–Moriya interaction. The lattices can be used for chirality transfer from merons to electrons and then to photons, and we show that the meron lattices can be used as spin injectors in nitride-based light-emitting diodes. The topology-induced spin light-emitting diode can provide 22.5% circularly polarized electroluminescence at room temperature and under zero magnetic field. Millimetre-scale meron lattices that are stable at room temperature and under zero magnetic field can be used as spin injectors in light-emitting diodes, providing 22.5% circularly polarized electroluminescence.