Evidence for Interface-Induced Strain and Its Influence on Photomagnetism in Prussian Blue Analogue Core–Shell Heterostructures, RbaCob[Fe(CN)6]c·mH2O@KjNik[Cr(CN)6]l·nH2O

Felts, Ashley C.; Andrus, Matthew J.; Knowles, Elizabeth S.; Quintero, Pedro A.; Ahir, Akhil R.; Risset, Olivia N.; Li, Carissa H.; Maurin, Isabelle; Halder, Gregory J.; Abboud, Khalil A.; Meisel, Mark W.; Talham, Daniel R.

doi:10.1021/acs.jpcc.5b10761

Cited by 40 publications

(43 citation statements)

References 44 publications

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“…Access to the elastic moduli of PBA nanoparticles, which are largely unknown in molecule-based materials (bulk and nano-object), is of paramount importance for developing applications based on the mechanical properties of molecular materials, such as microelectromechanical systems (MEMS) [36,37] or mechanically coupled nano-heterostructures. [22,24,38] It is important to stress also that in this work, we provide an accurate value of Poisson's ratio. The mechanical characterization of coordination networks is challenging, especially at the nanoscale, but it is necessary for the development of new applications and for understanding phase-change phenomena governed by electron-lattice coupling.…”

Section: Resultsmentioning

confidence: 95%

Elasticity of Prussian‐Blue‐Analogue Nanoparticles

et al. 2017

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Section: Resultsmentioning

confidence: 95%

Elasticity of Prussian‐Blue‐Analogue Nanoparticles

et al. 2017

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“…This latter is related in most cases to a charge transfer between the cyanide‐bridged metallic centers, denoted charge transfer induced spin transition (CTIST), which can occur due to thermal, pressure, or light stimuli . Recently, the groups of Mallah, Talham, and Maurin succeeded in synthesizing fairly monodisperse core–shell PBA@PBA nanoparticles with a CoFe core exhibiting CTIST and an epitaxial ferromagnetic shell consisting of either NiCr or CoCr analogs. Their experiments revealed in each case remarkable couplings between the properties of the constituents.…”

Section: Size Reduction Effectsmentioning

confidence: 99%

“…Thanks to the high quality crystalline samples a deep investigation of the underlying structural aspects became possible using high resolution X‐ray diffraction (XRD) and transmission electron microscopy (TEM) methods. As a representative example, Figure a shows a particle of the CTIST compound Rb 0.19 Co[Fe(CN) 6 ] 0.73 (1.4H 2 O)·1.8H 2 O embedded in a shell of the ferromagnetic K 0.28 Ni[Cr(CN) 6 ] 0.76 (1.4H 2 O)· n H 2 O . This structure exhibits photo‐induced and thermo‐induced changes in the magnetization of the KNiCr component, which is not light‐switchable on its own.…”

Section: Size Reduction Effectsmentioning

confidence: 99%

“…Upon cooling from 300 to 100 K the diffraction peaks of RbCoFe exhibit a spectacular shift to higher 2θ angles, which is also accompanied by a significant broadening of the peaks attributed to KNiCr. These effects can be inversed either by heating the particles back to 300 K or by light irradiation at 100 K. Reproduced with permission . Copyright 2016, American Chemical Society.…”

Section: Size Reduction Effectsmentioning

confidence: 99%

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Spin Crossover Nanomaterials: From Fundamental Concepts to Devices

et al. 2017

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Nanoscale spin crossover materials capable of undergoing reversible switching between two electronic configurations with markedly different physical properties are excellent candidates for various technological applications. In particular, they can serve as active materials for storing and processing information in photonic, mechanical, electronic, and spintronic devices as well as for transducing different forms of energy in sensors and actuators. In this progress report, a brief overview on the current state-of-the-art of experimental and theoretical studies of nanomaterials displaying spin transition is presented. Based on these results, a detailed analysis and discussions in terms of finite size effects and other phenomena inherent to the reduced size scale are provided. Finally, recent research devices using spin crossover complexes are highlighted, emphasizing both challenges and prospects.

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“…By downsizing of a bulk crystal, the volume ratio of the surface units to the bulk units can be increased significantly, leading to a coupling effect from the bulk structure and the surface units [17,20,21]. For instance, the meso-sized coordination polymers can accommodate guest molecules still, but their phase-change type would be changed owing to the suppressing effect of the surface energy [14,[22][23][24]. Downsizing can also shorten the diffusion distance when the guest molecules/ions travel inside, leading to high-rate adsorption/desorption ability.…”

Section: Introductionmentioning

confidence: 99%

Prussian Blue Analogue Mesoframes for Enhanced Aqueous Sodium-ion Storage

Sun

Zhang

2018

Crystals

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Mesostructure engineering is a potential avenue towards the property control of coordination polymers in addition to the traditional structure design on an atomic/molecular scale. Mesoframes, as a class of mesostructures, have short diffusion pathways for guest species and thus can be an ideal platform for fast storage of guest ions. We report a synthesis of Prussian Blue analogue mesoframes by top-down etching of cubic crystals. Scanning and transmission electron microscopy revealed that the surfaces of the cubic crystals were selectively removed by HCl, leaving the corners, edges, and the cores connected together. The mesoframes were used as a host for the reversible insertion of sodium ions with the help of electrochemistry. The electrochemical intercalation/de-intercalation of Na + ions in the mesoframes was highly reversible even at a high rate (166.7 C), suggesting that the mesoframes could be a promising cathode material for aqueous sodium ion batteries with excellent rate performance and cycling stability.

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Evidence for Interface-Induced Strain and Its Influence on Photomagnetism in Prussian Blue Analogue Core–Shell Heterostructures, Rb_aCo_b[Fe(CN)₆]_c·mH₂O@K_jNi_k[Cr(CN)₆]_l·nH₂O

Cited by 40 publications

References 44 publications

Elasticity of Prussian‐Blue‐Analogue Nanoparticles

Elasticity of Prussian‐Blue‐Analogue Nanoparticles

Spin Crossover Nanomaterials: From Fundamental Concepts to Devices

Prussian Blue Analogue Mesoframes for Enhanced Aqueous Sodium-ion Storage

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