Unusual Properties of Hydrogen-Bonded Ferroelectrics: The Case of Cobalt Formate

Hybrid organic-inorganic perovskites is a class of materials with diverse chemically tunable properties and outstanding potential for multifunctionality. We use first-principles simulations to predict room temperature ferroelectricity in a representative of the formate family, [NH_{2}NH_{3}][Co(HCOO...

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Published in:Physical review letters 2022-02, Vol.128 (7), p.077601-077601, Article 077601
Main Authors: Ghosh, P S, DeTellem, D, Ren, J, Witanachchi, S, Ma, S, Lisenkov, S, Ponomareva, I
Format: Article
Language:English
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Summary:Hybrid organic-inorganic perovskites is a class of materials with diverse chemically tunable properties and outstanding potential for multifunctionality. We use first-principles simulations to predict room temperature ferroelectricity in a representative of the formate family, [NH_{2}NH_{3}][Co(HCOO)_{3}]. The ferroelectricity arises as a "by-product" of structural transition driven by the stabilization of the hydrogen bond. As a consequence the coupling with the electric field is relatively weak giving origin to large intrinsic coercive fields and making material immune to the depolarizing fields known for its detrimental role in nanoscale ferroelectrics. Insensitivity to the electric field and the intrinsic dynamics of the order-disorder transition in such material leads to the supercoercivity defined as significant increase in the coercive field with frequency. Room temperature polarization measurements provide further support for the predictions.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.128.077601