Giant barocaloric effect in the ferroic organic-inorganic hybrid [TPrA][Mn(dca)3] perovskite under easily accessible pressures

Bermúdez‐García, Juan Manuel; Andújar, Manuel; Castro‐García, Socorro; López-Beceiro, Jorge; Artiaga, Ramón; Señarı́s-Rodrı́guez, M. A.

doi:10.1038/ncomms15715

Cited by 180 publications

(109 citation statements)

References 57 publications

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“…To date, giant BC effects have only been experimentally demonstrated near room temperature in a polymer 10 , a small number of relatively expensive magnetic materials 11 – 16 , a number of fluorites 17 – 20 , a hybrid perovskite 21 and a small number of ferro/ferrielectric materials 22 , 23 . Following the recent prediction of giant BC effects in fluoride-based superionic conductors at very high temperatures 24 , we demonstrate here giant BC effects nearer to room temperature in a powder of AgI, which is the prototypical solid electrolyte that was shown to display fast ionic conduction over one century ago 25 , 26 .…”

Section: Introductionmentioning

confidence: 99%

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

et al. 2017

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Current interest in barocaloric effects has been stimulated by the discovery that these pressure-driven thermal changes can be giant near ferroic phase transitions in materials that display magnetic or electrical order. Here we demonstrate giant inverse barocaloric effects in the solid electrolyte AgI, near its superionic phase transition at ~420 K. Over a wide range of temperatures, hydrostatic pressure changes of 2.5 kbar yield large and reversible barocaloric effects, resulting in large values of refrigerant capacity. Moreover, the peak values of isothermal entropy change (60 J K−1 kg−1 or 0.34 J K−1 cm−3) and adiabatic temperature changes (18 K), which we identify for a starting temperature of 390 K, exceed all values previously recorded for barocaloric materials. Our work should therefore inspire the study of barocaloric effects in a wide range of solid electrolytes, as well as the parallel development of cooling devices.

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Section: Introductionmentioning

confidence: 99%

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

et al. 2017

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“…Compounds that combine simultaneously organic and inorganic chemical groups are of great interest since they enlarge the range of structural possibilities that allow the coexistence and modulation of fundamental physical properties, increasing their multifunctional potential [ 1 ]. These hybrid inorganic-organic compounds have attracted great attention in the last years in view of their high technological potential in the areas of optoelectronics [ 2 ], photovoltaics [ 3 ], ferroelectrics [ 4 ], multiferroics [ 5 , 6 ], and, very recently, also in the field of barocaloric materials for solid-state cooling [ 7 , 8 ].…”

Section: Introductionmentioning

confidence: 99%

“…A very prominent member of this family is the manganese azide with A: [(CH 3 ) 4 N] + (n = 4), (TMA), (TMAMnN 3 ), the first azide reported to have a three-dimensional framework structure [ 17 ], which is now known to show coexistence of three ferroic orders (antiferroelectric, ferroelastic and magnetic bistability) [ 6 , 16 ]. In addition, in view of its very large entropy change at the ferroelastic phase transition (two times larger than in the case of the giant barocaloric hybrid perovskite [TPrA][Mn(dca) 3 ] (TPrA = (CH 3 CH 2 CH 2 ) 4 N + , dca = [N(CN) 2 ] − ) [ 8 ]), it has been first proposed [ 6 ] and recently experimentally proved that this material is a very promising barocaloric material [ 18 ].…”

Section: Introductionmentioning

confidence: 99%

Raman Spectroscopy Studies on the Barocaloric Hybrid Perovskite [(CH3)4N][Cd(N3)3]

et al. 2020

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Temperature-dependent Raman scattering and differential scanning calorimetry were applied to the study of the hybrid organic-inorganic azide-perovskite [(CH3)4N][Cd(N3)3], a compound with multiple structural phase transitions as a function of temperature. A significant entropy variation was observed associated to such phase transitions, |∆S| ~ 62.09 J·kg−1 K−1, together with both a positive high barocaloric (BC) coefficient |δTt/δP| ~ 12.39 K kbar−1 and an inverse barocaloric (BC) coefficient |δTt/δP| ~ −6.52 kbar−1, features that render this compound interesting for barocaloric applications. As for the obtained Raman spectra, they revealed that molecular vibrations associated to the NC4, N3– and CH3 molecular groups exhibit clear anomalies during the phase transitions, which include splits and discontinuity in the phonon wavenumber and lifetime. Furthermore, variation of the TMA+ and N3– modes with temperature revealed that while some modes follow the conventional red shift upon heating, others exhibit an unconventional blue shift, a result which was related to the weakening of the intermolecular interactions between the TMA (tetramethylammonium) cations and the azide ligands and the concomitant strengthening of the intramolecular bondings. Therefore, these studies show that Raman spectroscopy is a powerful tool to gain information about phase transitions, structures and intermolecular interactions between the A-cation and the framework, even in complex hybrid organic-inorganic perovskites with highly disordered phases.

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“…[1][2][3][4][5][6][7][8] Most extensively studied perovskite-type compounds contained HCOO − ligands but recently those with dicyanamide (N(CN) 2 −, dca) ligands also gained significant interest due to their complicated sequence of phase transitions as well as dielectric, barocaloric, and non-linear optical properties. [9][10][11][12][13][14] In this respect, former studies of tetrapropylammonium manganese dicyanamide (TPrAMn) showed that this compound exhibits only one structural phase transition at 330 K. [10] Further studies of Fe, Ni, and Co analogues revealed that these compounds undergo three structural phase transformations of the same character. [11] It is also worth noting that TPrAMn and TPrACo exhibit very strong pressure dependence of the phase transition temperatures and large phase transition entropies.…”

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confidence: 99%

“…[10,12] Thus, these compounds were shown to exhibit a large barocaloric effect. [12,14] TPrAM (M¼Mn, Fe, Co, Ni) compounds were studied using X-ray diffraction, thermal, and dielectric methods. [9][10][11] In spite of these studies, phase transition mechanisms of Mn, Fe, Co, and Ni analogues are still not well understood.…”

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confidence: 99%

Comparative studies of vibrational properties and phase transitions in perovskite‐like frameworks of [(C₃H₇)₄N][M(N(CN)₂)₃] with MMn, Co, Ni

Ciupa-Litwa

Ptak

Hanuza

et al. 2019

J Raman Spectroscopy

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We report for the first time phonon properties of [(C3H7)4N][M(N(CN)2)3] with MMn, Co, Ni (TPrAM), and theoretical Density Functional Theory (DFT) data for isolated TPrA+ cation obtained using harmonic and anharmonic approximation. Manganese compound undergoes one structural temperature‐induced phase transition, whereas others exhibit multiple structural phase transitions in a broad temperature ranges. Temperature‐dependent Raman studies let us obtain insight into mechanism of these transitions. The phase transition at about 330 K in TPrAMn involves mainly the ordering of the dca bridges coordinating Mn2+ ions and is accompanied by partial ordering of the TPrA+ cations and their shift in the cavities. However, the behavior of TPrANi is different. In particular, very large broadening of bands, attributed to vibrations of the dca and TPrA+ cations, revealed highly dynamic nature of these groups in all phases. This result indicates that observed phase transitions are associated with changing the dynamic disorder of both organic ions. Raman studies also show that all phase transformations are accompanied by slight modification in tilting of the NiN6 octahedra caused by shift of the TPrA+ ions in the cavities.

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Giant barocaloric effect in the ferroic organic-inorganic hybrid [TPrA][Mn(dca)3] perovskite under easily accessible pressures

Cited by 180 publications

References 57 publications

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

Raman Spectroscopy Studies on the Barocaloric Hybrid Perovskite [(CH3)4N][Cd(N3)3]

Comparative studies of vibrational properties and phase transitions in perovskite‐like frameworks of [(C₃H₇)₄N][M(N(CN)₂)₃] with MMn, Co, Ni

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Giant barocaloric effect in the ferroic organic-inorganic hybrid [TPrA][Mn(dca)3] perovskite under easily accessible pressures

Cited by 180 publications

References 57 publications

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

Giant barocaloric effects over a wide temperature range in superionic conductor AgI

Raman Spectroscopy Studies on the Barocaloric Hybrid Perovskite [(CH3)4N][Cd(N3)3]

Comparative studies of vibrational properties and phase transitions in perovskite‐like frameworks of [(C3H7)4N][M(N(CN)2)3] with MMn, Co, Ni

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Comparative studies of vibrational properties and phase transitions in perovskite‐like frameworks of [(C₃H₇)₄N][M(N(CN)₂)₃] with MMn, Co, Ni