Your search keyword '"Goto, Chigusa"' showing total 4 results

1. C 3 -Symmetric Luminescent Diketone with Amido-Linkage as a Polymorphic Fluorescence Emitter.

Author

Katsumi S, Kugai Y, Louis M, Morimoto T, Yamada M, Maisonneuve S, Goto C, Métivier R, Kawai T, and Allain C

Abstract

The study introduces a novel C 3 -symmetric β-diketone compound, BTA-D3, and its monomeric counterpart, D, with a focus on their synthetic procedure, photophysical properties and aggregation behavior. Both compounds exhibit characteristic absorption and weak fluorescence in solution, with BTA-D3 displaying higher absorption coefficients due to its larger number of diketone units. Density Functional Theory (DFT) calculations suggest increased co-planarity of diketone groups in BTA-D3. A significant finding is the Aggregation-Induced Emission (AIE) property of BTA-D3, as its fluorescence intensity increases dramatically when exposed to specific solvent ratios. The AIE behavior is attributed to intermolecular excitonic interaction between BTA-D3 molecules in self-organized aggregates. We also studied fluorescence anisotropy of BTA-D3 and D. Despite its larger size, BTA-D3 showed reduced anisotropy values because of efficient intramolecular energy migration among three diketone units. Furthermore, BTA-D3 demonstrates unique polymorphism, yielding different emission colors and structures depending on the solvent used. A unique approach is presented for promoting the growth of self-organized aggregate structures via solvent evaporation, leading to distinct fluorescence properties. This research contributes to the understanding of C 3 -symmetric structural molecules and provides insights into strategies for controlling molecular alignment to achieve diverse fluorescence coloration in molecular materials., (© 2024 Wiley‐VCH GmbH.)

Published

2024

2. Enhanced Thermoelectric Properties of Boron-Substituted Single-Walled Carbon Nanotube Films.

Author

Chiang WH, Iihara Y, Li WT, Hsieh CY, Lo SC, Goto C, Tani A, Kawai T, and Nonoguchi Y

Abstract

Atomic doping is the most fundamental approach to modulating the transport properties of carbon nanotubes. In this paper, we demonstrate the enhanced thermoelectric properties of boron-substituted single-walled carbon nanotube (B-SWCNT) films. The developed two-step synthesis of large quantities of B-SWCNTs readily enables the measurements of thermoelectricity of bulk B-SWCNT films. Complementary structural characterization implies the unique configuration of boron atoms at the doping sites of SWCNTs, successfully enabling carrier doping to SWCNTs. The developed boron substitution, in combination with chemical doping, is found to substantially improve the thermoelectric properties.

Published

2019

3. Thickness-dependent thermoelectric power factor of polymer-functionalized semiconducting carbon nanotube thin films.

Author

Nonoguchi Y, Takata A, Goto C, Kitano T, and Kawai T

Abstract

The effects of polymer structures on the thermoelectric properties of polymer-wrapped semiconducting carbon nanotubes have yet to be clarified for elucidating intrinsic transport properties. We systematically investigate thickness dependence of thermoelectric transport in thin films containing networks of conjugated polymer-wrapped semiconducting carbon nanotubes. Well-controlled doping experiments suggest that the doping homogeneity and then in-plane electrical conductivity significantly depend on film thickness and polymer species. This understanding leads to achieving thermoelectric power factors as high as 412 μW m -1  K -2 in thin carbon nanotube films. This work presents a standard platform for investigating the thermoelectric properties of nanotubes.

Published

2018

4. Water-Processable, Air-Stable Organic Nanoparticle-Carbon Nanotube Nanocomposites Exhibiting n-Type Thermoelectric Properties.

Author

Nonoguchi Y, Tani A, Ikeda T, Goto C, Tanifuji N, Uda RM, and Kawai T

Abstract

Water-dispersed organic base nanoparticles are utilized for the highly stable n-type doping of single-walled carbon nanotubes in aqueous dispersion. Long-term stability is often a critical challenge in the application of n-type organic conductors. The present n-type organic materials exhibit almost no degradation in the thermoelectric properties over months, in air., (© 2016 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2017