Repozytorium
Wyszukaj
Kolekcje
Inne
Ferroelectricity and ferroelasticity in organic inorganic hybrid (Pyrrolidinium)3[Sb2Cl9].
Autorzy
Rok wydania
2018
Czasopismo
Numer woluminu
30
Strony
4597-4608
DOI
10.1021/acs.chemmater.8b00962
Kolekcja
Język
Angielski
Typ publikacji
Artykuł
Perovskite-like materials exhibit desirable photophysical and electric properties that make them suitable for a remarkable breadth of applications in electronics and physics. In this contribution, we report on the multiphase ferroelectric and ferroelastic phenomena in a pyrrolidinium-based hybrid metal–organic material: (C4H8NH2)3[Sb2Cl9]. The title compound is the first pyrrolidinium derivative within the halobismuthates(III) and haloantimonates(III) families that is featured by the ferroelectric property. From a structural point of view, the crystal structure is built of [Sb2Cl9]3–∞perovskite-like layers, interdigitated by layers of pyrrolidinium cations. The rich solid-state dynamics of pyrrolidinium cations endowed (C4H8NH2)3[Sb2Cl9] with a complex sequence of temperature-dependent phase transitions. Remarkably, polar properties have been found to occur in all six phases, including room-temperature Phase I. Insights from variable-temperature single-crystal X-ray diffraction, dielectric spectroscopy, and T1 spin–lattice relaxation measurements revealed the general mechanism of most phase transitions, as related to the progressive ordering of nonequivalent pyrrolidinium cations. Noncentrosymmetry is probed by room-temperature second harmonic generation (SHG), while the ferroelectric property was evidenced through P(E) and dielectric measurements. The experimental values of spontaneous polarization were justified and analyzed in the context of theoretical values derived from quantum-chemical calculations. Optical measurements show that the integrity of the sample survives all of the phase transitions, despite sometimes significant deformations of the unit cell. The changes of symmetry associated with structural phase transitions are accompanied by an intriguing evolution of the ferroelastic domain structure with temperature.
Adres publiczny
http://dx.doi.org/10.1021/acs.chemmater.8b00962
Strona internetowa wydawcy
Podobne publikacje
Ferroelectricity, Piezoelectricity, and Unprecedented Starry Ferroelastic Patterns in Organic–Inorganic (CH3C(NH2)2)3[Sb2X9] (X = Cl/Br/I) Hybrids
Krupińska Aleksandra, Burzyńska Bogumiła, Kinzhybalo Vasyl, Dziuk Błażej, Szklarz Przemysław, Kajewski Dariusz, Zaręba Jan K., Drwęcka Ada, Zelewski Szymon J., Durlak Piotr, Zieliński Piotr, Sobieszczyk Paweł, Jakubas Ryszard, Piecha-Bisiorek Anna
Structural, Electric and Dynamic Properties of (Pyrrolidinium)3[Bi2I9] and (Pyrrolidinium)3[Sb2I9]: New Lead-Free, Organic–Inorganic Hybrids with Narrow Band Gaps
Rowińska Magdalena, Piecha-Bisiorek Anna, Medycki Wojciech, Durlak Piotr, Jakubas Ryszard, Gągor Anna
Organic-inorganic hybrid crystals, (2,4,6-CH3PyH)3Sb2Cl9 and (2,4,6-CH3PyH)3Bi2Cl9. Crystal structure characterization and tunneling of CH3 groups studied by 1H NMR and neutron spectroscopy.
Szklarz Przemysław, Jakubas Ryszard, Piecha-Bisiorek Anna, Bator Grażyna , Chański Michał, Medycki Wojciech, Wuttke J.