The Experts below are selected from a list of 104265 Experts worldwide ranked by ideXlab platform
Lei Jiang - One of the best experts on this subject based on the ideXlab platform.
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dual programmable shape Morphing and self healing organohydrogels through orthogonal supramolecular heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Jianqi Zhang, Zhichao Dong, Lei Jiang, Mingjie LiuAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
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Dual‐Programmable Shape‐Morphing and Self‐Healing Organohydrogels Through Orthogonal Supramolecular Heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Yichao Xu, Jianqi Zhang, Zhichao Dong, Lei JiangAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
Ziguang Zhao - One of the best experts on this subject based on the ideXlab platform.
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dual programmable shape Morphing and self healing organohydrogels through orthogonal supramolecular heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Jianqi Zhang, Zhichao Dong, Lei Jiang, Mingjie LiuAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
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Dual‐Programmable Shape‐Morphing and Self‐Healing Organohydrogels Through Orthogonal Supramolecular Heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Yichao Xu, Jianqi Zhang, Zhichao Dong, Lei JiangAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
Mingjie Liu - One of the best experts on this subject based on the ideXlab platform.
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dual programmable shape Morphing and self healing organohydrogels through orthogonal supramolecular heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Jianqi Zhang, Zhichao Dong, Lei Jiang, Mingjie LiuAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
Ruochen Fang - One of the best experts on this subject based on the ideXlab platform.
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dual programmable shape Morphing and self healing organohydrogels through orthogonal supramolecular heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Jianqi Zhang, Zhichao Dong, Lei Jiang, Mingjie LiuAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
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Dual‐Programmable Shape‐Morphing and Self‐Healing Organohydrogels Through Orthogonal Supramolecular Heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Yichao Xu, Jianqi Zhang, Zhichao Dong, Lei JiangAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
Xintao Zhou - One of the best experts on this subject based on the ideXlab platform.
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dual programmable shape Morphing and self healing organohydrogels through orthogonal supramolecular heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Jianqi Zhang, Zhichao Dong, Lei Jiang, Mingjie LiuAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
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Dual‐Programmable Shape‐Morphing and Self‐Healing Organohydrogels Through Orthogonal Supramolecular Heteronetworks
Advanced Materials, 2018Co-Authors: Ziguang Zhao, Shuyun Zhuo, Ruochen Fang, Longhao Zhang, Xintao Zhou, Yichao Xu, Jianqi Zhang, Zhichao Dong, Lei JiangAbstract:Programmable materials that can change their inherent shapes or properties are highly desirable due to their promising applications. However, among various programmable shape-Morphing materials, the single control route allows temporary states to recover the unchangeable former state, thus lacking the sophisticated programmability for their shape-encoding behaviors and mechanics. Herein, dual-programmable shape-Morphing organohydrogels featuring supramolecular heteronetworks are developed. In the system, the metallo-supramolecular hydrogel framework and micro-organogels featuring semicrystalline comb-type networks independently respond to different stimuli, thereby providing orthogonal dual-switching mechanics and ultrahigh mechanical strength. The supramolecular heteronetworks also possess excellent self-healing properties. More notably, such orthogonal supramolecular heteronetworks demonstrate hierarchical shape Morphing performance that far exceeds conventional shape-Morphing materials. Utilizing this dual programming strategy of the orthogonal supramolecular heteronetworks, the material's permanent shape can be manipulated in a step-wise shape Morphing process, thereby realizing sophisticated shape changes with a high degree of freedom. The organohydrogels can act as a biomimetic smart device for the on-demand control of unidirectional liquid transport. Based on these characteristics, it is anticipated that the supramolecular organohydrogels may serve as adaptive programmable materials for a variety of applications.
