Biomimetic Carbon Nanotube Films with Gradient Structure and Locally Tunable Mechanical Property

Lin, Zhiqiang; Gui, Xuchun; Zeng, Zhiping; Liang, Binghao; Liu, Ming; Zhu, Yuan; Cao, Anyuan; Tang, Zikang

doi:10.1002/adfm.201503341

Cited by 19 publications

(15 citation statements)

References 38 publications

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“…A mechanical gradient is often obtained by varying the structures or components along an axis of materials, including filler content, degree of orientation, and crosslinking density . Here, we introduced mechanical gradients by varying Cu‐DOU hard phase content.…”

Section: Resultsmentioning

confidence: 99%

Biomimetic Materials with Multiple Protective Functionalities

Liu

Zhang

Guan

et al. 2019

Adv Funct Materials

111

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Natural tissues possess superior material properties such as self-healing, mechanical robustness, and mechanical gradients that allow organisms to adapt and survive in dangerous environments. Although highly desired, imparting synthetic materials with these biomimetic protective features remains a challenge. Here, the versatile dimethylglyoxime-urethane (DOU) moiety is used to create a multifunctional polyurethane (DOU-PU). The reactivities of DOU including reversible dissociation, metal coordination, photolysis enabled self-healing, high strength and toughness, mechanical gradient formation, and spatially controlled functionalization. By incorporating DOU, a multifunctional protective film is produced with superior resistance to mechanical damage, rapid room temperature self-healing, and anti-counterfeiting features. This super biomimetic film is expected to be very useful for the protection of various types of valuable objects such as electronics, diplomas, currency, and automobiles.

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Section: Resultsmentioning

confidence: 99%

Biomimetic Materials with Multiple Protective Functionalities

Liu

Zhang

Guan

et al. 2019

Adv Funct Materials

111

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“…[ 104 ] In this report, a pre-designed pattern of MWNT arrays was contacttransferred to a PDMS sheet, and then a complementary pattern of SWNT arrays was transferred onto the MWNT-PDMS substrate, resulting in a 3D microarchitecture containing the SWNT and MWNT components with tunable nanotube orientation (Figure 4 d). [ 105 ] The fabrication process was similar except that we gradually and smoothly varied the volume ratio between the two carbon sources (xylene and dichlorobenzene) during feeding. Furthermore, inspired by the gradient structure of natural materials with gradual change in their macrostructure and related properties (bamboo shows a gradient structure in its cross section), our group reported a gradient CNT fi lm in which the nanotube distribution changed from aligned to completely random in a smooth and continuous way.…”

Section: Cnt Sponge-based Hierarchical or Hybrid Compositesmentioning

confidence: 99%

Section: Cnt Sponge-based Hierarchical or Hybrid Compositesmentioning

confidence: 99%

“…The above efforts were focused on the performance improvement by directly combining different CNT‐based structures into one integral composite. Furthermore, inspired by the gradient structure of natural materials with gradual change in their macrostructure and related properties (bamboo shows a gradient structure in its cross section), our group reported a gradient CNT film in which the nanotube distribution changed from aligned to completely random in a smooth and continuous way . The fabrication process was similar except that we gradually and smoothly varied the volume ratio between the two carbon sources (xylene and dichlorobenzene) during feeding.…”

Section: Preparation Of Cnt Sponges Aerogels and Hierarchical Compomentioning

confidence: 99%

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Carbon Nanotube Sponges, Aerogels, and Hierarchical Composites: Synthesis, Properties, and Energy Applications

Lin

Zeng

Gui

et al. 2016

Advanced Energy Materials

Self Cite

206

105

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Carbon nanotube (CNT) aerogels and sponges are macroscopic porous materials with a unique isotropic structure. CNTs make an interconnected 3D scaffold, therefore the resulting aerogels are robust, highly conductive, and flexible, enabling a much broader range of applications than aligned arrays and thin films, especially in energy and environmental areas. A comprehensive overview of the recent progress in isotropic CNT‐based macroscopic structures is provided, including their synthesis methods, structural characteristics, mechanical properties, and deformation mechanism, as well as potential applications in energy and environmental fields. In particular, this study focuses on the CNT sponges developed, which are high‐performance porous materials with many distinct properties such as their versatile deformations and shape recovery. Importantly, the CNT sponges provide a universal platform for designing and manufacturing a variety of hierarchical functional composites by introducing polymers or inorganic guests, thus greatly extend application areas from highly compressible electrodes for supercapacitors and batteries, catalysis, to environmental cleanup. Future research directions and associated challenges in this field are proposed.

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“…Some lateral gradients are able to obtain smooth transitions, but there are few examples due to the complex synthetic effort required to generate them. Notable examples of previously reported lateral gradients include photoinduced crosslinking of cellulose nanocrystals, ordering of carbon nanotube films, and cellulose nanofibril/polymer nanopapers . While these and other synthetic analogs are functional mechanical gradients, they often suffer from relatively small ranges in stiffness (∼1 order of magnitude), non‐continuous stepwise transitions, and require specialty equipment to fabricate.…”

Section: Figurementioning

confidence: 99%

Large Continuous Mechanical Gradient Formation via Metal–Ligand Interactions

Neal

Oldenhuis

Novitsky³

et al. 2017

Angewandte Chemie

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Mechanical gradients are often employed in nature to prevent biological materials from damage by creating as mooth transition from strong to weak that dissipates large forces.S ynthetic mimics of these natural structures are highly desired to improve distribution of stresses at interfaces and reduce contact deformation in manmade materials.C urrent synthetic gradient materials commonly suffer from non-continuous transitions,r elatively small gradients in mechanical properties,a nd difficult syntheses.I nspired by the polychaete worm jaw,w er eport an ovel approach to generate stiffness gradients in polymeric materials via incorporation of dynamic monodentate metal-ligand crosslinks.Through spatial control of metal ion content, we created ac ontinuous mechanical gradient that spans over a2 00-fold difference in stiffness, approaching the mechanical contrast observed in biological gradient materials.

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Biomimetic Carbon Nanotube Films with Gradient Structure and Locally Tunable Mechanical Property

Cited by 19 publications

References 38 publications

Biomimetic Materials with Multiple Protective Functionalities

Biomimetic Materials with Multiple Protective Functionalities

Carbon Nanotube Sponges, Aerogels, and Hierarchical Composites: Synthesis, Properties, and Energy Applications

Large Continuous Mechanical Gradient Formation via Metal–Ligand Interactions

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