Your search keyword '"He, Guang-Peng"' showing total 3 results

1. Visualizing the interfacial-layer-based epitaxial growth process toward organic core-shell architectures.

Author

Zhuo, Ming-Peng, Wei, Xiao, Li, Yuan-Yuan, Shi, Ying-Li, He, Guang-Peng, Su, Huixue, Zhang, Ke-Qin, Guan, Jin-Ping, Wang, Xue-Dong, Wu, Yuchen, and Liao, Liang-Sheng

Abstract

Organic heterostructures (OHTs) with the desired geometry organization on micro/nanoscale have undergone rapid progress in nanoscience and nanotechnology. However, it is a significant challenge to elucidate the epitaxial-growth process for various OHTs composed of organic units with a lattice mismatching ratio of > 3%, which is unimaginable for inorganic heterostructures. Herein, we have demonstrated a vivid visualization of the morphology evolution of epitaxial-growth based on a doped interfacial-layer, which facilitates the comprehensive understanding of the hierarchical self-assembly of core-shell OHT with precise spatial configuration. Significantly, the barcoded OHT with periodic shells obviously illustrate the shell epitaxial-growth from tips to center parts along the seeded rods for forming the core-shell OHT. Furthermore, the diameter, length, and number of periodic shells were modulated by finely tuning the stoichiometric ratio, crystalline time, and temperature, respectively. This epitaxial-growth process could be generalized to organic systems with facile chemical/structural compatibility for forming the desired OHTs.Organic heterostructures with controlled geometry on the micro and nanoscale are important in nanotechnology, but epitaxial growth processes with high lattice mismatching are challenging to achieve. Here, the authors report a visualisation process for morphology evolution on epitaxial growth. [ABSTRACT FROM AUTHOR]

Published

2024

2. Hierarchical Self‐Assembly of Organic Core/Multi‐Shell Microwires for Trichromatic White‐Light Sources.

Author

Zhuo, Ming‐Peng, Su, Yang, Qu, Yang‐Kun, Chen, Song, He, Guang‐Peng, Yuan, Yi, Liu, Hao, Tao, Yi‐Chen, Wang, Xue‐Dong, and Liao, Liang‐Sheng

Published

2021

3. Organic superstructure microwires with hierarchical spatial organisation.

Author

Zhuo, Ming-Peng, He, Guang-Peng, Wang, Xue-Dong, and Liao, Liang-Sheng

Subjects

ORGANIC synthesis, NANOSTRUCTURED materials, ORGANIZATION, CRYSTALLIZATION

Abstract

Rationally designing and precisely constructing the dimensions, configurations and compositions of organic nanomaterials are key issues in material chemistry. Nevertheless, the precise synthesis of organic heterostructure nanomaterials remains challenging owing to the difficulty of manipulating the homogeneous/heterogeneous-nucleation process and the complex epitaxial relationships of combinations of dissimilar materials. Herein, we propose a hierarchical epitaxial-growth approach with the combination of longitudinal and horizontal epitaxial-growth modes for the design and synthesis of a variety of organic superstructure microwires with accurate spatial organisation by regulating the heterogeneous-nucleation crystallisation process. The lattice-matched longitudinal and horizontal epitaxial-growth modes are separately employed to construct the primary organic core/shell and segmented heterostructure microwires. Significantly, these primary organic core/shell and segmented microwires are further applied to construct the core/shell-segmented and segmented-core/shell type's organic superstructure microwires through the implementation of multiple spatial epitaxial-growth modes. This strategy can be generalised to all organic microwires with tailored multiple substructures, which affords an avenue to manipulate their physical/chemical features for various applications. Rationally designing and precisely constructing the dimensions, configurations and compositions of organic micro- and nanomaterials are key issues in material chemistry, but remain challenging. Here, the authors realize the fine synthesis of organic superstructure microwires via a hierarchical epitaxial-growth approach. [ABSTRACT FROM AUTHOR]

Published

2021