Quantum criticality in a uniaxial organic ferroelectric

Tris-sarcosine calcium chloride (TSCC) is a highly uniaxial ferroelectric with a Curie temperature of approximately 130K. By suppressing ferroelectricity with bromine substitution on the chlorine sites, pure single crystals were tuned through a ferroelectric quantum phase transition. The resulting q...

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Bibliographic Details
Published in:arXiv.org 2014-10
Main Authors: Rowley, S E, Hadjimichael, M, Ali, M N, Durmaz, Y C, Lashley, J C, Cava, R J, Scott, J F
Format: Article
Language:English
Subjects:
Bromine
Calcium chloride
Chlorine
Critical point
Curie temperature
Dielectrics
Dipole interactions
Electric fields
Ferroelectric materials
Ferroelectricity
Phase transitions
Polarization
Single crystals
Time dependence
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Summary:Tris-sarcosine calcium chloride (TSCC) is a highly uniaxial ferroelectric with a Curie temperature of approximately 130K. By suppressing ferroelectricity with bromine substitution on the chlorine sites, pure single crystals were tuned through a ferroelectric quantum phase transition. The resulting quantum critical regime was investigated in detail - the first time for a uniaxial ferroelectric and for an organic ferroelectric - and was found to persist up to temperatures of at least 30K to 40K. The nature of long-range dipole interactions in uniaxial materials, which lead to non-analytical terms in the free-energy expansion in the polarization, predict a dielectric susceptibility varying as \(1/T^3\) close to the quantum critical point. Rather than this, we find that the dielectric susceptibility varies as \(1/T^2\) as expected and observed in better known multi-axial systems. We explain this result by identifying the ultra-weak nature of the dipoles in the TSCC family of crystals. Interestingly we observe a shallow minimum in the inverse dielectric function at low temperatures close to the quantum critical point in paraelectric samples that may be attributed to the coupling of quantum polarization and strain fields. Finally we present results of the heat capacity and electro-caloric effect and explain how the time dependence of the polarization in ferroelectrics and paraelectrics should be considered when making quantitative estimates of temperature changes induced by applied electric fields.
ISSN:2331-8422
DOI:10.48550/arxiv.1410.2908