Materials Nanoarchitectonics: Collaboration between Chem, Nano and Mat

Ariga, Katsuhiko

doi:10.1002/cnma.202300120

Cited by 7 publications

(1 citation statement)

References 220 publications

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“…π-Electronic systems exhibit fascinating electronic and electrooptical properties based on the tunable electronic states that affect their absorption and luminescence properties. The assembly of π-electronic systems in an ordered arrangement results in a variety of supramolecular nanoarchitectonics [ 1 , 2 ] to show unique electrooptical properties that cannot be observed in single molecules [ 3–7 ]. In particular, the solid-state photophysical properties of π-electronic systems depend on the stacking arrangement of their components.…”

Section: Introductionmentioning

confidence: 99%

Ion-pairing assemblies of π-extended anion-responsive organoplatinum complexes

Haketa,

Murakami,

Maeda

2024

Science and Technology of Advanced Materials

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Pt II complexes of π-extended dipyrrolyldiketones were synthesized as anion-responsive π-electronic molecules. The dipyrrolyldiketone Pt II complexes exhibited red-shifted absorption and photoluminescence properties. In the solid state, [1 + 1]-type anion complexes formed charge-by-charge ion-pairing assemblies when combined with countercations. Detailed theoretical studies of the packing structures revealed favorable interactions between the planar anion complexes and π-electronic cations.

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Section: Introductionmentioning

confidence: 99%

Ion-pairing assemblies of π-extended anion-responsive organoplatinum complexes

Haketa,

Murakami,

Maeda

2024

Science and Technology of Advanced Materials

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Liquid–Liquid Interfacial Nanoarchitectonics

Ariga

2023

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Science in the small world has become a crucial key that has the potential to revolutionize materials technology. This trend is embodied in the postnanotechnology concept of nanoarchitectonics. The goal of nanoarchitectonics is to create bio‐like functional structures, in which self‐organized and hierarchical structures are working efficiently. Liquid–liquid interface like environments such as cell membrane surface are indispensable for the expression of biological functions through the accumulation and organization of functional materials. From this viewpoint, it is necessary to reconsider the liquid–liquid interface as a medium where nanoarchitectonics can play an active role. In this review, liquid–liquid interfacial nanoarchitectonics is classified by component materials such as organic, inorganic, carbon, and bio, and recent research examples are discussed. Examples discussed in this paper include molecular aggregates, supramolecular polymers, conductive polymers film, crystal‐like capsules, block copolymer assemblies, covalent organic framework (COF) films, complex crystals, inorganic nanosheets, colloidosomes, fullerene assemblies, all‐carbon π‐conjugated graphite nanosheets, carbon nanoskins and fullerphene thin films at liquid–liquid interfaces. Furthermore, at the liquid–liquid interface using perfluorocarbons and aqueous phases, cell differentiation controls are discussed with the self‐assembled structure of biomaterials. The significance of liquid–liquid interfacial nanoarchitectonics in the future development of materials will then be discussed.

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Composite Nanoarchitectonics Towards Method for Everything in Materials Science

Ariga

2024

J Inorg Organomet Polym

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The characteristic feature of a biofunctional system is that components with various functions work together. These multi-components are not simply mixed together, but are rationally arranged. The fundamental technologies to do this in an artificial system include the synthetic chemistry of the substances that make the component unit, the science and techniques for assembling them, and the technology for analyzing their nanoostructures. A new concept, nanoarchitectonics, can play this role. Nanoarchitectonics is a post-nanotechnology concept that involves building functional materials that reflect the nanostructures. In particular, the approach of combining and building multiple types of components to create composite materials is an area where nanoarchitectonics can be a powerful tool. This review summarizes such examples and related composite studies. In particular, examples are presented in the areas of catalyst & photocatalyst, energy, sensing & environment, bio & medical, and various other functions and applications to illustrate the potential for a wide range of applications. In order to show the various stages of development, the examples are not only state-of-the-art, but also include those that are successful developments of existing research. Finally, a summary of the examples and a brief discussion of future challenges in nanoarchitectonics will be given. Nanoarchitectonics is applicable to all materials and aims to establish the ultimate methodology of materials science.

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Materials Nanoarchitectonics: Collaboration between Chem, Nano and Mat

Cited by 7 publications

References 220 publications

Ion-pairing assemblies of π-extended anion-responsive organoplatinum complexes

Ion-pairing assemblies of π-extended anion-responsive organoplatinum complexes

Liquid–Liquid Interfacial Nanoarchitectonics

Composite Nanoarchitectonics Towards Method for Everything in Materials Science

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