Your search keyword '"Sasaki, Toshiyuki"' showing total 4 results

1. Mechanical twinning in organic crystals.

Author

Sasaki, Toshiyuki

Subjects

*TWINNING (Crystallography), *CRYSTALS, *YIELD strength (Engineering), *SINGLE crystals, *ANISOTROPY

Abstract

Mechanical twinning, which enables crystalline solids to deform reversibly beyond their elastic limit, has been getting much attention in recent progressive studies on flexible organic crystals. In addition to the deformability, organic single crystals can obtain new functionalities or directions of their functions with anisotropy can be controlled based on mechanical twinning. Owing to these features, mechanical twinning will be one of the key mechanisms in developing the next-generation flexible organic crystalline materials. This highlight describes recent advances in mechanical twinning in organic crystals to help clarify the potential and challenges faced for future developments. For this purpose, the areas of focus are the molecular mechanisms and functions in addition to qualitative and quantitative aspects of the deformability. [ABSTRACT FROM AUTHOR]

Published

2022

2. Elastic deformability and luminescence of crystals of polyhalogenated platinum(II)–bipyridine complexes.

Author

Yoshida, Masaki, Makino, Yusuke, Sasaki, Toshiyuki, Sakamoto, Shunichi, Takamizawa, Satoshi, Kobayashi, Atsushi, and Kato, Masako

Subjects

LUMINESCENCE, PLATINUM, CRYSTALS, SINGLE crystals, CHARGE transfer

Abstract

Single crystals showing elastic flexibility have attracted increasing attention as next-generation soft materials. Herein, we successfully developed a series of polyhalogenated platinum(II)–bipyridine complexes showing solvent-of-crystallisation-dependent elastic flexibility. Notably, methanol-solvated crystals were the first examples of flexible crystals showing assembly-induced luminescence arising from the triplet metal–metal-to-ligand charge transfer (3MMLCT) excited state. Furthermore, factors inducing elastic deformability based on the packing structures of the crystals were explored. [ABSTRACT FROM AUTHOR]

Published

2021

3. A Multidirectional Superelastic Organic Crystal by Versatile Ferroelastical Manipulation.

Author

Sasaki, Toshiyuki, Sakamoto, Shunichi, Takasaki, Yuichi, and Takamizawa, Satoshi

Subjects

*CRYSTAL orientation, *CRYSTALS, *SINGLE crystals, *SOFT robotics, *GEOMETRIC shapes

Abstract

Mechanical twinning changes atomic, molecular, and crystal orientations along with directions of the anisotropic properties of the crystalline materials while maintaining single crystallinity in each domain. However, such deformability has been less studied in brittle organic crystals despite their remarkable anisotropic functions. Herein we demonstrate a direction‐dependent mechanical twinning that shows superelasticity in one direction and ferroelasticity in two other directions in a single crystal of 1,3‐bis(4‐methoxyphenyl)urea. The crystal can undergo stepwise twinning and ferroelastically forms various shapes with multiple domains oriented in different directions, thereby affording a crystal that shows superelasticity in multiple directions. This adaptability and shape recoverability in a ferroelastic and superelastic single crystal under ambient conditions are of great importance in future applications of organic crystals as mechanical materials, such as in soft robotics. [ABSTRACT FROM AUTHOR]

Published

2020

4. Shape Rememorization of an Organosuperelastic Crystal through Superelasticity–Ferroelasticity Interconversion.

Author

Sakamoto, Shunichi, Sasaki, Toshiyuki, Sato‐Tomita, Ayana, and Takamizawa, Satoshi

Subjects

*SINGLE crystals, *CRYSTALS, *FERROELASTICITY, *GEOMETRIC shapes, *CANNING & preserving

Abstract

As altering permanent shapes without loss of material function is of practical importance for material molding, especially for elastic materials, shape‐rememorization ability would enhance the utility of elastic crystalline materials. Since diffusionless plastic deformability can preserve the crystallinity of materials, the interconversion of diffusionless mechanical deformability between superelasticity and ferroelasticity could enable shape rememorization of superelastic single crystals. This study demonstrates the shape rememorization of an organosuperelastic single crystal of 1,4‐dicyanobenzene through time‐reversible interconversion of superelasticity–ferroelasticity relaxation by holding the mechanically twinned crystal without heating. The shape‐rememorization ability of the organosuperelastic crystal indicates the compatibility of superelasticity (antiferroelasticity) and ferroelasticity as well as the intrinsic workability of organic crystalline materials capable of recovering their crystal functions under mild conditions. [ABSTRACT FROM AUTHOR]

Published

2019