Mixed‐Valence Nickel Bis(azamacrocycle) Compounds with Ghost‐Leg‐type Sheets

Hashiguchi, Ryota; Otsubo, Kenji; Maesato, Mitsuhiko; Sugimoto, Kunihisa; Fujiwara, Akihiko; Kitagawa, Hiroshi

doi:10.1002/ange.201610515

“…Among coordination complexes, we have focused on the 1D halogen‐bridged transition metal complexes (MX‐chains) because their electronic states can be controlled by structural components such as metal ions, halides, organic ligands, and counteranions [10] . Recently, by connecting the MX‐chains with organic ligands, a variety of metal–organic ladder compounds (so‐called MX‐ladders) based on the dimensional extension of MX‐chains have been obtained; these include the two‐legged ladder, [11] four‐legged tube, [12] and 2D extended two‐legged ladder (2D ghost‐legged sheet) [13] (Figure 1). In these MX‐ladder compounds, unique electronic state, unique sorption properties and high proton conductivity were observed.…”

Section: Figurementioning

confidence: 99%

“… Schematics of two‐legged MX‐ladder, [11] 2D extended two‐legged MX‐ladder (2D ghost‐legged sheet), [13] and 3D extended two‐legged MX‐ladder compounds (this work).…”

Section: Figurementioning

confidence: 99%

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

Liang,

Otsubo,

Wakabayashi

et al. 2024

Angewandte Chemie

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Ladder systems situated in the dimensional crossover region have attracted much attention because their electronic states and physical properties depend strongly on the electronic correlations among the constituent legs. Generally, two‐/three‐legged transition metal‐oxide ladder compounds are studied as representative ladder systems, but two‐/three‐dimensional (2D/3D) extensions based on such ladder systems with a few numbers of legs are difficult because of the extreme synthesis conditions. Here, for the first time, we report the successful creation of a 3D extended two‐legged ladder compound, [Pt(en)(dpye)I]2(NO3)4·2H2O (en = ethylenediamine; dpye = 1,2‐Di(4‐pyridyl)ethane), which is obtained by simple oxidative polymerization of a small Pt macrocyclic complex using elemental I2. The unique 3D extended lattice consists of 1D mixed‐valence halogen‐bridged metal chains (···Pt–I–Pt–I···) and helically arranged macrocyclic units as the constituent legs and rungs, as confirmed by single‐crystal X‐ray diffraction. Diffuse X‐ray scattering analyses and optical measurements revealed that the out‐of‐phase mixed‐valence Pt2+/Pt4+ arrangement arises from the weak interchain correlation among adjacent legs. In addition, this compound shows an increase in proton conductivity by a factor of up to 1000, depending on humidity.

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A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

Liang,

Otsubo,

Wakabayashi

et al. 2024

Angew Chem Int Ed

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Ladder systems situated in the dimensional crossover region have attracted much attention because their electronic states and physical properties depend strongly on the electronic correlations among the constituent legs. Generally, two‐/three‐legged transition metal‐oxide ladder compounds are studied as representative ladder systems, but two‐/three‐dimensional (2D/3D) extensions based on such ladder systems with a few numbers of legs are difficult because of the extreme synthesis conditions. Here, for the first time, we report the successful creation of a 3D extended two‐legged ladder compound, [Pt(en)(dpye)I]2(NO3)4·2H2O (en = ethylenediamine; dpye = 1,2‐Di(4‐pyridyl)ethane), which is obtained by simple oxidative polymerization of a small Pt macrocyclic complex using elemental I2. The unique 3D extended lattice consists of 1D mixed‐valence halogen‐bridged metal chains (···Pt–I–Pt–I···) and helically arranged macrocyclic units as the constituent legs and rungs, as confirmed by single‐crystal X‐ray diffraction. Diffuse X‐ray scattering analyses and optical measurements revealed that the out‐of‐phase mixed‐valence Pt2+/Pt4+ arrangement arises from the weak interchain correlation among adjacent legs. In addition, this compound shows an increase in proton conductivity by a factor of up to 1000, depending on humidity.

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Porous Mn²⁺ Magnet with a Pt−Cl Framework: Correlation between Water Vapor Adsorption/Desorption and Slow Magnetic Relaxation

Nakajima

¹

,

Uchida

²

,

Yoshida

³

et al. 2022

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We report the water adsorption/desorption behavior and dynamic magnetic properties of the PtÀ Cl chain complex [{[Pt(en) The framework structures of 1 and 1DH are identical, and both complexes underwent slow magnetic relaxation. However, the magnetic relaxation times for 1DH were shorter than those for 1, meaning that the dynamic magnetic properties were controlled upon water vapor adsorption/desorption. From detailed analyses of the dynamic magnetic behavior, a phonon-bottleneck effect contributes to the magnetic relaxation processes. We discuss the mechanism for the changes in the magnetic relaxation processes upon dehydration in terms of the heat capacity and thermal conductivity.

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Mixed‐Valence Nickel Bis(azamacrocycle) Compounds with Ghost‐Leg‐type Sheets

Cited by 4 publications

References 58 publications

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

Porous Mn²⁺ Magnet with a Pt−Cl Framework: Correlation between Water Vapor Adsorption/Desorption and Slow Magnetic Relaxation

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Mixed‐Valence Nickel Bis(azamacrocycle) Compounds with Ghost‐Leg‐type Sheets

Cited by 4 publications

References 58 publications

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

A Three‐Dimensionally Extended Metal–Organic Ladder Compound Exhibiting Proton Conduction

Porous Mn2+ Magnet with a Pt−Cl Framework: Correlation between Water Vapor Adsorption/Desorption and Slow Magnetic Relaxation

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Porous Mn²⁺ Magnet with a Pt−Cl Framework: Correlation between Water Vapor Adsorption/Desorption and Slow Magnetic Relaxation