Identification of spin wave resonances and crystal field levels in simple chromites RCrO<sub>3</sub> (R = Pr, Sm, Er) at low temperatures in the THz spectral region
We report on THz absorption spectroscopy combined with high magnetic fields of polycrystalline RCrO<sub>3</sub> (R = Pr, Sm, Er) aiming understanding spin wave resonances at their low temperature magnetic phases. Our measurements show that the temperature, and the implicit anisotropies a...
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| Autores principales: | , , , , , , |
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| Formato: | Articulo Preprint |
| Lenguaje: | Inglés |
| Publicado: |
2018
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| Materias: | |
| Acceso en línea: | http://sedici.unlp.edu.ar/handle/10915/124335 |
| Aporte de: |
| Sumario: | We report on THz absorption spectroscopy combined with high magnetic fields of polycrystalline RCrO<sub>3</sub> (R = Pr, Sm, Er) aiming understanding spin wave resonances at their low temperature magnetic phases. Our measurements show that the temperature, and the implicit anisotropies at which the Cr<sup>3+</sup> spin reorientation at TSR takes place, are determinant on the ferromagnetic-like (FM) and the antiferromagnetic-like (AFM) spin modes being optically active. It is found that they are dependent on Rare Earth 4f moment and ion size. We also studied temperature and field dependence of crystal field levels in the same spectroscopic region. Pr<sup>3+</sup> non-Kramers emerges at 100 K and Zeeman splits. An observed absence of spin wave resonances in PrCrO<sub>3</sub> is attributed to Pr<sup>3+</sup> remaining paramagnetic. In SmCrO<sub>3</sub> near cancelation of the spin and orbital moments is proposed as the possible reason for not detecting Sm<sup>3+</sup> ground state transitions. Here, the FM and AFM resonant modes harden when the temperature decreases and split linearly under applied fields at 5 K and below. In ErCrO<sub>3</sub> the Er<sup>3+</sup> Kramers doublet becomes active at about the TSR onset. Each line further experiences Zeeman splitting under magnetic fields while an spin reversal induced by a ∼2.5 T field, back to the Γ4 (Fz) from the Γ1 phase at 2 K, produces a secondary splitting. The 5 K AFM and FM excitations in ErCrO<sub>3</sub> have a concerted frequency-intensity temperature dependence and a shoulder pointing to the Er<sup>3+</sup> smaller ion size also disrupting the two magnetic sublattice approximation. Both resonances reduce to one when the temperature is lowered to 2 K in the Γ1 representation. Our findings have important implications on the complex interplay in the magneto-electrodynamics associated with the Rare-Earth 4f – 3d transition metal spin coupling and the structural A site instabilities in perovskite multiferroics. |
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