Photoswitching topology in polymer networks with metal–organic cages as crosslinks

Polymer networks can have a range of desirable properties such as mechanical strength, wide compositional diversity between different materials, permanent porosity, convenient processability and broad solvent compatibility 1 , 2 . Designing polymer networks from the bottom up with new structural mot...

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Bibliographic Details
Published in:Nature (London) 2018-08, Vol.560 (7716), p.65-69
Main Authors: Gu, Yuwei, Alt, Eric A., Wang, Heng, Li, Xiaopeng, Willard, Adam P., Johnson, Jeremiah A.
Format: Article
Language:English
Subjects:
639/301/923/1027
639/301/923/1028
639/301/923/966
Actuators
Analysis
Automation
Cages
Chemical composition
Control equipment
Crosslinking
Defects
Elasticity
Environmental effects
Humanities and Social Sciences
Hydrogels
Irradiation
Letter
Ligands
Manufacturing engineering
Mechanical properties
Mechanical stimuli
Monte Carlo simulation
multidisciplinary
Network architectures
Network topologies
Organic chemistry
Organometallic compounds
Polymer industry
Polymer physics
Polymers
Porosity
Properties
Robotics
Robotics industry
Science
Science (multidisciplinary)
Self healing materials
Self-assembly
Shear modulus
Signal transduction
Stem cells
Stiffness
Stress relaxation
Switching theory
Topology
Ultraviolet radiation
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Description
Summary:Polymer networks can have a range of desirable properties such as mechanical strength, wide compositional diversity between different materials, permanent porosity, convenient processability and broad solvent compatibility 1 , 2 . Designing polymer networks from the bottom up with new structural motifs and chemical compositions can be used to impart dynamic features such as malleability or self-healing, or to allow the material to respond to environmental stimuli 3 – 8 . However, many existing systems exhibit only one operational state that is defined by the material’s composition and topology 3 – 6 ; or their responsiveness may be irreversible 7 , 9 , 10 and limited to a single network property 11 , 12 (such as stiffness). Here we use cooperative self-assembly as a design principle to prepare a material that can be switched between two topological states. By using networks of polymer-linked metal–organic cages in which the cages change shape and size on irradiation, we can reversibly switch the network topology with ultraviolet or green light. This photoswitching produces coherent changes in several network properties at once, including branch functionality, junction fluctuations, defect tolerance, shear modulus, stress-relaxation behaviour and self-healing. Topology-switching materials could prove useful in fields such as soft robotics and photo-actuators and also provide model systems for fundamental polymer physics studies. Using topology-switching metal–ligand cages to crosslink polymer networks produces gels whose chemical and mechanical properties can be radically and reversibly switched on irradiation.
ISSN:0028-0836
1476-4687
DOI:10.1038/s41586-018-0339-0