Bibliographic Details
| Title: |
Fabrication of single-crystalline YFeO3 films with large antiferromagnetic domains. |
| Authors: |
Wang, Cong1 (AUTHOR), Lippmaa, Mikk1 (AUTHOR), Nakatsuji, Satoru1,2,3,4 (AUTHOR) satoru@phys.s.u-tokyo.ac.jp |
| Superior Title: |
Journal of Applied Physics. 3/21/2024, Vol. 135 Issue 11, p1-8. 8p. |
| Subject Terms: |
*THIN films, *PULSED laser deposition, *MAGNETIC anisotropy, *MAGNETIC properties, *MAGNETIC fields, *SUPERCONDUCTING quantum interference devices |
| Abstract: |
The antiferromagnetic orthoferrite YFeO3 possesses fascinating magnetic properties for spintronics, such as terahertz spin dynamics, ultrafast domain wall motion, and long magnon decay length. YFeO3 belongs to a special family of antiferromagnets that show an unusually strong non-trivial Kerr response due to its weak ferromagnetism. The highly stable antiferromagnetic domains without any spontaneous spin rotation transitions below the 645 K Néel temperature may be useful for nanoscale device applications. We report the successful fabrication of high-quality twinning-free (110)-oriented YFeO3 films by pulsed laser deposition. Detailed structural and magnetic characterization revealed that the crystal structure and magnetic properties of the YFeO3 films are comparable to bulk single crystals. We show that the spin rotation under high magnetic fields follows the two-sublattice approximation model. The film surface is atomically flat with step-terrace surface morphology. A longitudinal magneto-optic Kerr (MOKE) rotation of 10 mdeg was observed at room temperature, which is consistent with earlier reports on bulk single crystals. The in-plane anisotropy of the Kerr response corresponds to the obtained magnetic anisotropy from the SQUID measurement. The large MOKE signal enables the imaging of antiferromagnetic domains and their reversal. The domain size was found to be larger than 100 μm. These high-quality YFeO3 thin films facilitate the fabrication of antiferromagnetic spintronic devices and provide a convenient platform for studying various spin-related phenomena in thin films and at interfaces. [ABSTRACT FROM AUTHOR] |
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| Database: |
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