Ayaka Ikeda scite author profile

Icosahedral noble-metal 13-atom nanoclusters (NCs) can form connected structures, which can be regarded as superatomic molecules, by vertex sharing. However, there have been very few reports on the superatomic molecules formed using silver (Ag) as the base element. In this study, we synthesized [Ag23Pd2(PPh3)10Cl7]0 (Pd = palladium, PPh3 = triphenylphosphine, Cl = chloride), in which two icosahedral 13-atom NCs are connected, and elucidated its geometric and electronic structures to clarify what type of superatomic molecules can be synthesized. The results revealed that [Ag23Pd2(PPh3)10Cl7]0 is a synthesizable superatomic molecule. Single crystal x-ray diffraction analysis showed that the metal–metal distances in and between the icosahedral structures of [Ag23Pd2(PPh3)10Cl7]0 are slightly shorter than those of previously reported [Ag23Pt2(PPh3)10Cl7]0, whereas the metal–PPh3 distances are slightly longer. On the basis of several experiments and density functional theory calculations, we concluded that [Ag23Pd2(PPh3)10Cl7]0 and previously reported [Ag23Pt2(PPh3)10Cl7]0 are more stable than [Ag25(PPh3)10Cl7]2+ because of their stronger superatomic frameworks (metal cores). These findings are expected to lead to clear design guidelines for creation of new superatomic molecules.

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Atomically precise thiolate‐protected gold nanoclusters: Current status of designability of the structure and physicochemical properties

Hossain

Hirayama

Ikeda

et al. 2022

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Thiolate (SR)‐protected gold nanoclusters (Aun(SR)m NCs) are a rare type of material capable of simultaneously exhibiting multiple physicochemical properties well‐suited to specific applications, including photoluminescence, thermocatalysis, electrocatalysis, photocatalysis, magnetism, and optical activity. Over the past several decades, there has been tremendous progress in our understanding of the structure and physicochemical properties of Aun(SR)m NCs, resulting in the ability to fine‐tune the characteristics of these materials. It is therefore helpful to examine the extent to which the properties of Aun(SR)m and related metal NCs can now be adjusted based on design. This review presents representative examples of previous studies concerning the geometry, electronic structure, luminescence properties, catalysis, magnetism and optical activity of Aun(SR)m and related metal NCs and discusses the current status of the designability of these NCs to impart specific structural and physicochemical characteristics. This information is expected to accelerate the fabrication of highly functional materials based on Aun(SR)m and related metal NCs.

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Selective formation of [Au₂₃(SPh^tBu)₁₇]⁰, [Au₂₆Pd(SPh^tBu)₂₀]⁰ and [Au₂₄Pt(SC₂H₄Ph)₇(SPh^tBu)₁₁]⁰ by controlling ligand-exchange reaction

et al. 2022

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Vertex‐Shared Linear Superatomic Molecules: Stepping Stones to Novel Materials Composed of Noble Metal Clusters

et al. 2023

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Extremely small metal clusters composed of noble metal atoms (M) have orbitals similar to those of atoms and therefore can be thought of as artificial atoms or superatoms. If these superatoms can be assembled into molecular analogs, it might be possible to create materials with new characteristics and properties that are different from those of existing substances. Therefore, the concept of superatomic molecules has attracted significant attention. The present review focuses on vertex‐shared linear M12n+1 superatomic molecules formed via the sharing of a single metal atom between M13 superatoms having icosahedral cores and summarizes the knowledge obtained to date in this regard. This summary discusses the most suitable ligand combinations for the synthesis of M12n+1 superatomic molecules along with the valence electron numbers, stability, optical absorption characteristics, and luminescence properties of the M12n+1 superatomic molecules fabricated to date. This information is expected to assist in the production of many M12n+1 superatomic molecules with novel structures and physicochemical properties in the future.

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Key factors for connecting silver-based icosahedral superatoms by vertex sharing

et al. 2023

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Metal nanoclusters composed of noble elements such as gold (Au) or silver (Ag) are regarded as superatoms. In recent years, the understanding of the materials composed of superatoms, which are often called superatomic molecules, has gradually progressed for Au-based materials. However, there is still little information on Ag-based superatomic molecules. In the present study, we synthesise two di-superatomic molecules with Ag as the main constituent element and reveal the three essential conditions for the formation and isolation of a superatomic molecule comprising two Ag13−xMx structures (M = Ag or other metal; x = number of M) connected by vertex sharing. The effects of the central atom and the type of bridging halogen on the electronic structure of the resulting superatomic molecule are also clarified in detail. These findings are expected to provide clear design guidelines for the creation of superatomic molecules with various properties and functions.

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Ayaka Ikeda

[Ag23Pd2(PPh3)10Cl7]: A new family of synthesizable bi-icosahedral superatomic molecules

Atomically precise thiolate‐protected gold nanoclusters: Current status of designability of the structure and physicochemical properties

Selective formation of [Au₂₃(SPh^tBu)₁₇]⁰, [Au₂₆Pd(SPh^tBu)₂₀]⁰ and [Au₂₄Pt(SC₂H₄Ph)₇(SPh^tBu)₁₁]⁰ by controlling ligand-exchange reaction

Vertex‐Shared Linear Superatomic Molecules: Stepping Stones to Novel Materials Composed of Noble Metal Clusters

Key factors for connecting silver-based icosahedral superatoms by vertex sharing

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Ayaka Ikeda

[Ag23Pd2(PPh3)10Cl7]: A new family of synthesizable bi-icosahedral superatomic molecules

Atomically precise thiolate‐protected gold nanoclusters: Current status of designability of the structure and physicochemical properties

Selective formation of [Au23(SPhtBu)17]0, [Au26Pd(SPhtBu)20]0 and [Au24Pt(SC2H4Ph)7(SPhtBu)11]0 by controlling ligand-exchange reaction

Vertex‐Shared Linear Superatomic Molecules: Stepping Stones to Novel Materials Composed of Noble Metal Clusters

Key factors for connecting silver-based icosahedral superatoms by vertex sharing

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Product

Resources

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Selective formation of [Au₂₃(SPh^tBu)₁₇]⁰, [Au₂₆Pd(SPh^tBu)₂₀]⁰ and [Au₂₄Pt(SC₂H₄Ph)₇(SPh^tBu)₁₁]⁰ by controlling ligand-exchange reaction