Room temperature large spontaneous exchange bias in hard-soft antiferromagnetic composite BiFeO3-TbMnO3
Prince Kr. Gupta, Surajit Ghosh, Shiv Kumar, Arkadeb Pal, Rahul Singh,, Abhishek Singh, Somnath Roy, Eike F. Schwier, Masahiro Sawada, Takeshi, Matsumura, Kenya Shimada, Hong-Ji Lin, Yi-Ying Chin, A.K. Ghosh, Sandip, Chatterjee

TL;DR
This study demonstrates room temperature giant spontaneous exchange bias in a BiFeO3-TbMnO3 composite, driven by interfacial strain-mediated magnetoelectric coupling and a 2D dilute antiferromagnetic layer, with implications for magnetic device applications.
Contribution
It reveals a novel room temperature exchange bias mechanism in a hard-soft antiferromagnetic composite, highlighting interfacial effects and strain-mediated coupling as key factors.
Findings
Giant exchange bias of 5-778 Oe persists at room temperature.
Interfacial 2D dilute antiferromagnet layer influences magnetic properties.
XMCD confirms canted antiferromagnetic order and charge transfer effects.
Abstract
We report the presence of giant spontaneous exchange bias (HSEB) in a hard and soft antiferromagnetic composite of BiFeO3-TbMnO3 (BFO-TMO in 7:3 and 8:2 ratio). The HSEB varies between 5-778Oe, but persists up to room temperature with a maximum near a spin reorientation transition temperature observed from magnetization vs. temperature measurement in Zero-field cooled (ZFC) and Field cooled (FC) modes. Isothermal remnant magnetization measurements at room temperature indicate the presence of an interfacial layer of a 2 dimensional dilute antiferromagnet in a field (2D DAFF). A stable value of the exchange bias has been observed via training effect measurements which signify the role of interfacial exchange coupling in the system. Based on the experimental results we explain the presence of the giant spontaneous exchange bias on the basis of a strong strain-mediated…
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