Switchable electric polarization and ferroelectric domains in a metal-organic-framework

Jain, Prashant K.; Stroppa, Alessandro; Nabok, Dmitrii; Marino, Antigone; Rubano, Andrea; Paparo, D.; Matsubara, Masakazu; Nakotte, H.; Fiebig, Manfred; Picozzi, Silvia; Choi, Eun Sang; Cheetham, Anthony K.; Draxl, Claudia; Dalal, Naresh S.; Zapf, V. S.

doi:10.1038/npjquantmats.2016.12

Cited by 109 publications

(97 citation statements)

References 43 publications

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“…16 This dovetails with a recent report of sizable magnetoelectric coupling at elevated temperatures. 21 These findings suggest that there may be a magnetically-driven transition at higher fields -beyond the phase space that has been thus far explored. 18,22 Other perovskite-like materials including the rare earth manganites also sport exotic phase diagrams, 23 providing additional motivation for measurements of [(CH 3 ) 2 NH 2 ]Mn(HCOO) 3 under external stimuli.…”

Section: Introductionmentioning

confidence: 83%

“…At the same time, fits to the susceptibility in the vicinity of the ferroelectric transition, 16 our magnetization data above T N which extends to 12 K (Fig. 4), and the sizable magnetoelectric coupling at elevated temperatures (up to 40 K) 21 indicate that short range interactions are important, although the temperature range is more limited. Nuclear magnetic resonance measurements on the Zn analog, on the other hand, reveal that T C itself is insensitive to magnetic field and that there is no ordering of the amine -at least up to 5 T. 44 That spin resides on the metal-organic framework is consistent with our spin density calculations in Fig.…”

Section: Resultsmentioning

confidence: 99%

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Magnetic field-temperature phase diagram of multiferroic [(CH3)2NH2]Mn(HCOO)3<

et al. 2017

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We combined pulsed field magnetization and first principles spin density calculations to reveal the magnetic field-temperature phase diagram and spin state character in multiferroic [(CH3)2NH2]Mn(HCOO)3. Despite similarities with the rare earth manganites, the phase diagram is analogous to other Mn-based quantum magnets with a 0.31 T spin flop, a 15.3 T transition to the fully polarized state, and short range correlations that persist above the ordering temperature. The experimentally accessible saturation field opens the door to exploration of the high field phase.

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Section: Introductionmentioning

confidence: 83%

Section: Resultsmentioning

confidence: 99%

Magnetic field-temperature phase diagram of multiferroic [(CH3)2NH2]Mn(HCOO)3<

et al. 2017

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“…It was found that compounds with Mn exhibit strong d-π hybridization, which leads to partially filled low-spin levels, in contrast to compounds with transition metals, for which the Fermi energy is weakly split by spin due to weak d-π hybridization and magnetic interaction. In this case, the 3D MOF, (CH 3 ) 2 NH 2 Mn(HCOO) 3 , exhibits a perovskite architecture with ferroelectric domains, the magnetic states of which can be controlled by an electric field at temperatures below 180 K. [93] At present, structures with reversible/nonreversible phasechange effects are applied for triggers, switchers and other active elements for optical, magnetic, and microelectronic devices. [62] In the case of chained MOFs such as NU-901, one can observe electrochromic switching between yellow and deep blue hues by applied potential, due to a single-electron redox reaction on their pyrene-based linkers.…”

Section: Phase-change Effectmentioning

confidence: 99%

Metal–Organic Frameworks in Modern Physics: Highlights and Perspectives

et al. 2019

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Owing to the synergistic combination of a hybrid organic–inorganic nature and a chemically active porous structure, metal–organic frameworks have emerged as a new class of crystalline materials. The current trend in the chemical industry is to utilize such crystals as flexible hosting elements for applications as diverse as gas and energy storage, filtration, catalysis, and sensing. From the physical point of view, metal–organic frameworks are considered molecular crystals with hierarchical structures providing the structure‐related physical properties crucial for future applications of energy transfer, data processing and storage, high‐energy physics, and light manipulation. Here, the perspectives of metal–organic frameworks as a new family of functional materials in modern physics are discussed: from porous metals and superconductors, topological insulators, and classical and quantum memory elements, to optical superstructures, materials for particle physics, and even molecular scale mechanical metamaterials. Based on complementary properties of crystallinity, softness, organic–inorganic nature, and complex hierarchy, a description of how such artificial materials have extended their impact on applied physics to become the mainstream in material science is offered.

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“…Metal organic framework (MOF) materials having ABX 3 perovskite structure, where A is the dimethyl ammonium cation (DMA + ; DMA cation), B = Mn, and X is HCOO − formate ion, are known to exhibit multiferroic properties with an electrical ordering between 180 and 190 K and magnetic ordering at still lower temperature (8–10 K) . At room temperature, this compound crystallizes in the trigonal space group R3̅c, where the DMA cations in the perovskite‐like cages are orientationally disordered.…”

Section: Introductionmentioning

confidence: 99%

“…This orientational ordering is related to the freezing of the internal rotation of DMA + ion with respect to the C–C axis of DMA cation, induced by hydrogen‐bond formation between the nitrogen atoms of the DMA + ions and the oxygen atoms of the formate frameworks, as shown in Figure S1b. The nature of this ferroelectric transition has been probed using several techniques such as electrical polarization, crystallographic methods, neutron scattering, dielectric measurements, thermal, magnetic, and electron paramagnetic resonance (EPR) methods . Optical techniques sensitive to local structural changes such as infrared (IR) and Raman spectroscopy have been carried out on DMMn to investigate the actual microstructural mechanism involved .…”

Section: Introductionmentioning

confidence: 99%

Raman spectroscopic studies across the ferroelectric transition in cobalt substituted dimethyl amine manganese formate

Premila

Bharathi

Rajaraman

et al. 2018

J Raman Spectroscopy

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Temperature‐dependent Raman studies, across the ferroelectric transition, Tc, in the metal organic framework material, [(CH3)2NH2][Mn(HCOO)3]—DMMn, and its cobalt (Co) doped analogues have been carried out to look for the changes in the lattice and intramolecular modes associated with the orientational ordering of the central dimethyl ammonium cation (DMA+) driven by the hydrogen‐bonded interaction between the DMA cation and the formate anion. A systematic decrease of the transition temperature with increased Co doping has been observed that correlates with results of specific heat measurements. The low‐wavenumber librational mode of the DMA cation shows a dramatic softening and narrowing of line width, across the transition, providing direct evidence of the slowing down of the rotation of the DMA cation associated with the orientational ordering. The evolution with temperature of the N‐H stretch modes of the DMA cation suggests that invoking the hydrogen‐bonding interactions alone is not enough to understand the observed decrease in the ferroelectric transition with Co doping in DMMn. A subtle interplay between the framework flexibility, size/charge of the metal cation, and the hydrogen‐bonding tendency finally decides the transition temperature in these materials.

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Switchable electric polarization and ferroelectric domains in a metal-organic-framework

Cited by 109 publications

References 43 publications

Magnetic field-temperature phase diagram of multiferroic [(CH3)2NH2]Mn(HCOO)3<

Magnetic field-temperature phase diagram of multiferroic [(CH3)2NH2]Mn(HCOO)3<

Metal–Organic Frameworks in Modern Physics: Highlights and Perspectives

Raman spectroscopic studies across the ferroelectric transition in cobalt substituted dimethyl amine manganese formate

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