Solvent-Assisted 4D Programming and Reprogramming of Liquid Crystalline Organogels

Binjie Jin; Jiaqi Liu; Yunpeng Shi; Guancong Chen; Qian Zhao; Shu Yang

doi:10.1002/adma.202107855

Solvent-Assisted 4D Programming and Reprogramming of Liquid Crystalline Organogels

Binjie Jin
, Jiaqi Liu
, Yunpeng Shi
, Guancong Chen
, Qian Zhao
, Shu Yang^*

^*Corresponding author for this work

University of Pennsylvania
Zhejiang University

Research output: Contribution to journal › Article › peer-review

106 Scopus citations

Abstract

Encoding molecular ordering during liquid crystalline network (LCN) formation endows preprogrammed but fixed shape morphing in response to external stimuli. The incorporation of dynamic covalent bonds enables shape reprogramming but also permanently alters the network structures. Here, an entropic approach that can program complex shapes via directed solvent evaporation from an isotropic LCN organogel is discoursed. Different shapes can be erased and reprogrammed from the same LCN on demand depending on the modes of deformation of the organogel during solvent evaporation. The ability to decouple network synthesis and molecular alignment relaxes the requirements to LCN chemistry and alignment methods, allowing for the realization of a variety of origami/kirigami structures and 4D shape morphing of LCNs printed from the digital light processing technique with unattainable spatial and temporal controls.

Original language	English
Article number	2107855
Journal	Advanced Materials
Volume	34
Issue number	5
DOIs	https://doi.org/10.1002/adma.202107855
State	Published - 3 Feb 2022
Externally published	Yes

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title = "Solvent-Assisted 4D Programming and Reprogramming of Liquid Crystalline Organogels",

abstract = "Encoding molecular ordering during liquid crystalline network (LCN) formation endows preprogrammed but fixed shape morphing in response to external stimuli. The incorporation of dynamic covalent bonds enables shape reprogramming but also permanently alters the network structures. Here, an entropic approach that can program complex shapes via directed solvent evaporation from an isotropic LCN organogel is discoursed. Different shapes can be erased and reprogrammed from the same LCN on demand depending on the modes of deformation of the organogel during solvent evaporation. The ability to decouple network synthesis and molecular alignment relaxes the requirements to LCN chemistry and alignment methods, allowing for the realization of a variety of origami/kirigami structures and 4D shape morphing of LCNs printed from the digital light processing technique with unattainable spatial and temporal controls.",

author = "Binjie Jin and Jiaqi Liu and Yunpeng Shi and Guancong Chen and Qian Zhao and Shu Yang",

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doi = "10.1002/adma.202107855",

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T1 - Solvent-Assisted 4D Programming and Reprogramming of Liquid Crystalline Organogels

AU - Jin, Binjie

AU - Liu, Jiaqi

AU - Shi, Yunpeng

AU - Chen, Guancong

AU - Zhao, Qian

AU - Yang, Shu

PY - 2022/2/3

Y1 - 2022/2/3

N2 - Encoding molecular ordering during liquid crystalline network (LCN) formation endows preprogrammed but fixed shape morphing in response to external stimuli. The incorporation of dynamic covalent bonds enables shape reprogramming but also permanently alters the network structures. Here, an entropic approach that can program complex shapes via directed solvent evaporation from an isotropic LCN organogel is discoursed. Different shapes can be erased and reprogrammed from the same LCN on demand depending on the modes of deformation of the organogel during solvent evaporation. The ability to decouple network synthesis and molecular alignment relaxes the requirements to LCN chemistry and alignment methods, allowing for the realization of a variety of origami/kirigami structures and 4D shape morphing of LCNs printed from the digital light processing technique with unattainable spatial and temporal controls.

AB - Encoding molecular ordering during liquid crystalline network (LCN) formation endows preprogrammed but fixed shape morphing in response to external stimuli. The incorporation of dynamic covalent bonds enables shape reprogramming but also permanently alters the network structures. Here, an entropic approach that can program complex shapes via directed solvent evaporation from an isotropic LCN organogel is discoursed. Different shapes can be erased and reprogrammed from the same LCN on demand depending on the modes of deformation of the organogel during solvent evaporation. The ability to decouple network synthesis and molecular alignment relaxes the requirements to LCN chemistry and alignment methods, allowing for the realization of a variety of origami/kirigami structures and 4D shape morphing of LCNs printed from the digital light processing technique with unattainable spatial and temporal controls.

UR - https://www.scopus.com/pages/publications/85120999283

U2 - 10.1002/adma.202107855

DO - 10.1002/adma.202107855

M3 - 文章

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AN - SCOPUS:85120999283

SN - 0935-9648

VL - 34

JO - Advanced Materials

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ER -

Solvent-Assisted 4D Programming and Reprogramming of Liquid Crystalline Organogels

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