Supramolecularly Engineered Functional π-Assemblies Based on Complementary Hydrogen-Bonding Interactions

Yagai, Shiki

doi:10.1246/bcsj.20140261

Cited by 154 publications

(82 citation statements)

References 160 publications

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“…[5][6][7][8][9][10][11][12][13][14][15][16][17] In order to achieve these functionalities, highlyordered, adaptive nanostructures formed via a cooperative supramolecular polymerization mechanism are highly desirable. 18 The introduction of orthogonal noncovalent interactions, 19 from which hydrogen bonding and combinations with other secondary interactions are by far the most exploited ones, 20 represents a rational means for this purpose.…”

Section: Introductionmentioning

confidence: 99%

Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Allampally

Muñoz

Chansai

et al. 2016

Chemistry A European J

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Section: Introductionmentioning

confidence: 99%

Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Allampally

Muñoz

Chansai

et al. 2016

Chemistry A European J

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“…303 These fabrication processes may be linked even with organic synthetic approaches 304,305 and supramolecular organization. 306,307 However, more important efforts for practical usage and industrial applications would be those for mass production, 63,308310 which would be a crucial step for further development of 2D materials. …”

Section: Resultsmentioning

confidence: 99%

Two-Dimensional (2D) Nanomaterials towards Electrochemical Nanoarchitectonics in Energy-Related Applications

Khan

Ghosh

Pradhan

et al. 2017

Bulletin of the Chemical Society of Japan

389

197

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includes self-assembled fullerene crystals design from zero-to-higher dimensions, mesoporous fullerene crystals and their conversion into graphitic mesoporous carbons, high surface area nanoporous carbon material design from agro-waste for electrochemical supercapacitors and VOC adsorption. Somobrata AcharyaSomobrata Acharya received his Ph.D. degree from Jadavpur University, India. He is currently Associate Professor in the Centre for Advanced Materials (CAM), Indian Association for the Cultivation of Science (IACS), India. He is carrying out research in interdisciplinary areas probing structure-property relationship and possible applications of semiconductor nanomaterials in the areas of energy generation and consumption. His research area includes heterostructures, 2D nanostructures, superlattices, supramolecular assemblies and their suitable applications. Katsuhiko ArigaKatsuhiko Ariga received his Ph.D. degree from Tokyo Institute of Technology. He is currently the Director of Supermolecules Group and Principal Investigator of World Premier International (WPI) Research Centre for Materials Nanoarchitectonics (MANA), the National Institute for Materials Science (NIMS). His research is oriented to supramolecular chemistry, surface science, and functional nanomaterials (Langmuir-Blodgett film, layer-by-layer assembly, self-organized materials, sensing and drug delivery, molecular recognition, mesoporous material, etc. and he is now trying to combine them into a unified field. AbstractDesigning nanoscale components and units into functional defined systems and materials has recently received attention as a nanoarchitectonics approach. In particular, exploration of nanoarchitectonics in two-dimensions (2D) has made great progress these days. Basically, 2D nanomaterials are a center of interest owing to the large surface areas suitable for a variety of surface active applications. The increasing demands for alternative energy generation have significantly promoted the rational design and fabrication of a variety of 2D nanomaterials since the discovery of graphene. In 2D nanomaterials, the charge carriers are confined along the thickness while being allowed to move along the plane. Owing to the large planar area, 2D nanomaterials are highly sensitive to external stimuli, a characteristic suitable for a variety of surface active applications including electrochemistry. Because of the unique

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“…While there are several strategies for preparing hybrid materials, molecular self-assembly using noncovalent interactions [5][6][7][8][9][10] is considered a simple and efficient approach to the preparation of hybrid materials [11][12][13][14][15][16] . The nanoscale and mesoscale ordering of the building blocks in these hybrid materials and the resultant morphological features determine their functional properties, which can be modified by exploiting the reversible and adaptive nature of noncovalent interactions 17,18 .…”

Section: Introductionmentioning

confidence: 99%

“…16b) 87 . Absorption and fluorescence studies showed that the aqueous dispersion of 40/SWNTs exclusively contained small-diameter nanotubes such as (6, 5: d = 0.757 nm) and (8,3: d = 0.782 nm), whereas the large diameter ones ( (7,5), (8,4), and (7, 6); d = 0.829, 0.840, and 0.895 nm) were removed from the assynthesized SWNTs samples by centrifugation. The rotation around the -C≡C-bonds of the phenyleneethynylene unit of 40 played a crucial role in the helical wrapping of SWNTs having a definite chirality.…”

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confidence: 99%

Hybrid materials of 1D and 2D carbon allotropes and synthetic π-systems

et al. 2018

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Self-assembled synthetic hybrid materials are an important class of artificial materials with potential applications in various fields ranging from optoelectronics to medicine. The noncovalent interactions involved in the self-assembly process offer a facile way to create hybrid materials with unique and interesting properties. In this context, selfassembled hybrid materials based on carbon nanotubes (CNTs), graphene, and graphene derivatives such as graphene oxide (GO) and reduced graphene oxide (RGO) are of particular significance. These composites are solution processable, generally exhibit enhanced electrical, mechanical, and chemical properties, and find applications in the fields of light harvesting, energy storage, optoelectronics, sensors, etc. Herein, we present a brief summary of recent developments in the area of self-assembled functional hybrid materials comprising one-dimensional (1D) or twodimensional (2D) carbon allotropes and synthetic π-systems such as aromatic molecules, gelators, and polymers.

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Supramolecularly Engineered Functional π-Assemblies Based on Complementary Hydrogen-Bonding Interactions

Cited by 154 publications

References 160 publications

Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Two-Dimensional (2D) Nanomaterials towards Electrochemical Nanoarchitectonics in Energy-Related Applications

Hybrid materials of 1D and 2D carbon allotropes and synthetic π-systems

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Supramolecularly Engineered Functional π-Assemblies Based on Complementary Hydrogen-Bonding Interactions

Cited by 154 publications

References 160 publications

Control over the Self‐Assembly Modes of PtII Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Control over the Self‐Assembly Modes of PtII Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Two-Dimensional (2D) Nanomaterials towards Electrochemical Nanoarchitectonics in Energy-Related Applications

Hybrid materials of 1D and 2D carbon allotropes and synthetic π-systems

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Product

Resources

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Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks

Control over the Self‐Assembly Modes of Pt^II Complexes by Alkyl Chain Variation: From Slipped to Parallel π‐Stacks