Critical role of water structure around interlayer ions for ion storage in layered double hydroxides

Sudare, Tomohito; Yamaguchi, Takuro; Ueda, Mizuki; Shiiba, Hiromasa; Tanaka, Hideki; Tipplook, Mongkol; Hayashi, Fumitaka; Teshima, Katsuya

doi:10.1038/s41467-022-34124-9

Cited by 21 publications

(17 citation statements)

References 48 publications

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“…Layered double hydroxides (LDHs) are layered compounds that have been known for a long time but have recently been attracting much attention owing to their wide variety of advanced functions. Layered nickel hydroxides and Fe-containing LDHs are promising as electrode catalysts for water oxidation. , Solid base catalysis for organic chemical reactions, − photocatalysis for CO 2 reduction, , and ion storage materials are also important research fields for green chemistry and sustainable energies. Recently, developed techniques have enabled the synthesis of LDH nanomaterials, such as nanocrystals − and nanosheets .…”

Section: Introductionmentioning

confidence: 99%

Molecular-Level Pictures of Chemical and Structural Transformations of Mg–Al Layered Double Hydroxide Crystals (Mg/Al = 2) at Elevated Temperatures

Matsuda,

Okuda,

Kawashimo

et al. 2023

J. Phys. Chem. C

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Mg−Al layered double hydroxides (Mg−Al LDHs) are crystalline compounds with layered structures composed of hydroxide layers and interlayer anions such as CO 3 2−. A detailed understanding of the thermal decomposition behaviors is indispensable for materials design toward promising applications such as CO 2 adsorbents. Here, we report that the thermal decomposition behavior of a well-crystallized Mg−Al LDH having an Mg/Al atomic ratio of 2, where all hydroxyl groups experience an identical chemical environment, provides quantitative evidence for and clear molecular-/atomic-level pictures of the multistep transformation of the crystals at elevated temperature. Thermal decomposition is found to occur in multi-steps of (1) release of the interlayer water, (2) dehydroxylation of just one-third of hydroxyl groups accompanied by the formation of coordinatively unsaturated sites followed by coordination of carbonate to metals, and (3) collapse of the layered structure at a higher temperature. The stepwise structural transformations are not ascribable to different coordination environments of hydroxyl groups. The reason is possibly that the structure after the partial dehydroxylation of the metal hydroxide layers is rather stable. Structural optimization by first-principles DFT calculations and its powder X-ray diffraction simulation supported the interpretations for and the molecular-level pictures of the structural transformations. These results resolve the various interpretations on the structural change of the crystals.

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Section: Introductionmentioning

confidence: 99%

Molecular-Level Pictures of Chemical and Structural Transformations of Mg–Al Layered Double Hydroxide Crystals (Mg/Al = 2) at Elevated Temperatures

Matsuda,

Okuda,

Kawashimo

et al. 2023

J. Phys. Chem. C

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“…In brief, high nitrate ion intercalation in the dilute regime is driven by enhanced interlayer binding forces, while the capacity that remains at a low level in concentrated regime is due to weakened interlayer binding forces owing to further nitrate ion inclusion into the interlayer spaces. Remarkably, our previous study suggested that this transformation in the interlayer environment of the LDHs structure includes a 2D to 3D transformation of the hydrogen-bonding network between the interlayer ions and water molecules …”

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confidence: 93%

“…QCM-D is an effective in situ measurement tool for understanding the ion dynamics in matter. From the change in the frequency (Δ f ) value, the real-time mass transfer of inter(de)intercalating ion in association with water can be monitored. − Importantly, dissipation (Δ D ) monitoring has been long utilized for studying the dynamic deformation behaviors accompanying viscoelastic change in water-containing soft matter. , The viscoelasticity of the LDHs represents the overall interlayer binding force . Therefore, by simultaneously monitoring the Δ D values and Δ f , the dynamic change in the interlayer binding force along with mass transfer of LDHs upon nitrate intercalation is studied (Figure b).…”

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confidence: 99%

“…32,33 The viscoelasticity of the LDHs represents the overall interlayer binding force. 34 Therefore, by simultaneously monitoring the ΔD values and Δf, the dynamic change in the interlayer binding force along with mass transfer of LDHs upon nitrate intercalation is studied (Figure 3b). For this, the as-prepared LDHs were deposited on SiO 2 -coated Au electrodes (Figure S3) and examined by QCM-D. Wherein, at first, a concentrated aqueous 200 mM NaCl aqueous solution was flown and subsequently an aqueous 200 mM NaNO 3 solution was flown by changing flow channel (Figure 3b).…”

mentioning

confidence: 99%

“…Remarkably, our previous study suggested that this transformation in the interlayer environment of the LDHs structure includes a 2D to 3D transformation of the hydrogen-bonding network between the interlayer ions and water molecules. 34 LDHs-R with the 3R 1 polytype exhibited an induction period in the early nitrate ion storage regime (Figure 3c), during which there was an apparent absence of variations in both the dissipation and the frequency. After the induction period, a gradual decrease in dissipation and an increase in frequency were observed.…”

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confidence: 99%

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Layer-Stacking Sequence Governs Ion-Storage in Layered Double Hydroxides

Sudare

Ueda

Yamaguchi

et al. 2023

J. Phys. Chem. Lett.

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In layered materials, the layer-stacking sequence allows the tuning of ion transport and storage properties by modulating the host–ion interactions. However, unlike in the case of cations, the relationship between the stacking sequence and anion transport and storage properties is less clearly understood. Herein, we demonstrate that the stacking sequence governs the nitrate-storage properties of layered double hydroxides (LDHs); the 2H 1 polytype enhances the nitrate-storage capacity to 400% of that of the 3R 1 polytype. A quartz crystal microbalance with dissipation monitoring combined with multimodal ex situ experiments indicated that the high ion-storage capacity of the 2H 1 polytype originates from the soft nature of LDHs lattices, which facilitates nitrate with minimal lattice changes. In contrast, the rigid lattice of the 3R 1 sequence requires a notably large lattice expansion, which is detrimental to ion storage. Our findings can aid the rational design of anion-host interaction-derived functionalities.

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Real Time Tracking of Nanoconfined Water‐Assisted Ion Transfer in Functionalized Graphene Derivatives Supercapacitor Electrodes

Padinjareveetil,

Pykal,

Bakandritsos

et al. 2024

Advanced Science

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Water molecules confined in nanoscale spaces of 2D graphene layers have fascinated researchers worldwide for the past several years, especially in the context of energy storage applications. The water molecules exchanged along with ions during the electrochemical process can aid in wetting and stabilizing the layered materials resulting in an anomalous enhancement in the performance of supercapacitor electrodes. Engineering of 2D carbon electrode materials with various functionalities (oxygen (─O), fluorine (─F), nitrile (─C≡N), carboxylic (─COOH), carbonyl (─C═O), nitrogen (─N)) can alter the ion/water organization in graphene derivatives, and eventually their inherent ion storage ability. Thus, in the current study, a comparative set of functionalized graphene derivatives—fluorine‐doped cyanographene (G–F–CN), cyanographene (G–CN), graphene acid (G–COOH), oxidized graphene acid (G‐COOH (O)) and nitrogen superdoped graphene (G–N) is systematically evaluated toward charge storage in various aqueous‐based electrolyte systems. Differences in functionalization on graphene derivatives influence the electrochemical properties, and the real‐time mass exchange during the electrochemical process is monitored by electrochemical quartz crystal microbalance (EQCM). Electrogravimetric assessment revealed that oxidized 2D acid derivatives (G–COOH (O)) are shown to exhibit high ion storage performance along with maximum water transfer during the electrochemical process. The complex understanding of the processes gained during supercapacitor electrode charging in aqueous electrolytes paves the way toward the rational utilization of graphene derivatives in forefront energy storage applications.

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Critical role of water structure around interlayer ions for ion storage in layered double hydroxides

Cited by 21 publications

References 48 publications

Molecular-Level Pictures of Chemical and Structural Transformations of Mg–Al Layered Double Hydroxide Crystals (Mg/Al = 2) at Elevated Temperatures

Molecular-Level Pictures of Chemical and Structural Transformations of Mg–Al Layered Double Hydroxide Crystals (Mg/Al = 2) at Elevated Temperatures

Layer-Stacking Sequence Governs Ion-Storage in Layered Double Hydroxides

Real Time Tracking of Nanoconfined Water‐Assisted Ion Transfer in Functionalized Graphene Derivatives Supercapacitor Electrodes

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