h−ErMnO3 absorbance, reflectivity, and emissivity in the terahertz to mid-infrared from 2 to 1700 K: Carrier screening, Fröhlich resonance, small polarons, and bipolarons

We report the temperature-dependent THz to mid-infrared response of hexagonal- ErMnO3 using absorption, reflectivity, and emissivity techniques from 2 to 1700 K. At low temperatures, lowest frequency vibrational modes, which extend up the lock-in ferroelectric temperature, coexist with paramagnon ex...

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Bibliographic Details
Published in:Physical review. B 2020-10, Vol.102 (13), p.1
Main Authors: Massa, Néstor E, del Campo, Leire, Holldack, Karsten, Canizarès, Aurélien, Phuoc, Vinh Ta, Kayser, Paula, Alonso, José Antonio
Format: Article
Language:English
Subjects:
Emissivity
Ferroelectric materials
Ferroelectricity
High temperature
Infrared analysis
Lattice vibration
Low temperature
Phase transitions
Phonons
Polarons
Raman spectra
Rare earth elements
Reflectance
Resonance scattering
Temperature
Temperature dependence
Thermal expansion
Unit cell
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Summary:We report the temperature-dependent THz to mid-infrared response of hexagonal- ErMnO3 using absorption, reflectivity, and emissivity techniques from 2 to 1700 K. At low temperatures, lowest frequency vibrational modes, which extend up the lock-in ferroelectric temperature, coexist with paramagnon excitations and are associated with well-defined crystal-field rare-earth pure magnetic replicas in an intriguing phonon-magnetic convergence enhancing the multiferroic character of h−ErMnO3. Increasing the temperature, a number of vibrational bands close to the space group predicted undergo profile broadening and softening. In particular, a distinctive set of bands in the 288–329−cm−1 (300 K) range has a component whose profile is carrier screened becoming nearly fully blurred in the intermediate phase between ∼830 and ∼1500 K. Below TC ∼ 830 K this asymmetric band, having one component still partially screened, further splits as spin phonon interaction and the tripling of the unit cell take place revealing at TN ∼ 79 K a delicate balance of long- and short-range interactions. Ambient Raman scattering brings up evidence of a Fröhlich resonance due to Coulomb interactions between carriers and the macroscopic field linked to the corresponding longitudinal optical-phonon mode. We found it is dynamically correlated to the hexagonal c -axis negative thermal expansion. Quantitative analyses of the mid-infrared (MIR) optical conductivity show that it also plays a role in small polarons and mediates in high-temperature bipolarones. Bipolaron profiles at high temperatures change as the sample opacity increases when at ∼900 K straight stripes turn curly toward complex vortex-antivortex domain patterns in the paraelectric phase. At still higher temperatures a low-frequency Drude contribution is triggered by electron hopping signaling an insulator-metal phase transition at ∼1600 K while the MIR response suggests coexistence between single small polarons and bipolarons. On closing, we draw a parallel with improper ferroelectrics sustaining a lattice incommensurate intermediate phase and unit-cell tripling. We argue that in the h−RMnO3 (R = rare earth, Y) family of compounds the intermediate phase be considered incommensurate with onset at TINC ∼ 1500 K and ferroelectric lock-in at TC ∼ 830 K delimiting this regime in h−ErMnO3.
ISSN:2469-9950
2469-9969
DOI:10.1103/PhysRevB.102.134305