Ultrastrong Graphene Films via Long-Chain π-Bridging

Wan, Sijie; Chen, Ying; Wang, Yanlei; Li, Guangwen; Wang, Guorui; Liu, Luqi; Zhang, Jianqi; Liu, Yuzhou; Xu, Zhiping; Tomsia, Antoni P.; Jiang, Lei; Cheng, Qunfeng

doi:10.1016/j.matt.2019.04.006

Cited by 118 publications

(91 citation statements)

References 69 publications

(100 reference statements)

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“…To investigate the effect of different levels of interface interaction including hydrogen bonding, 32 ionic bonding, [33][34][35] π-π bonding, [36][37][38] covalent bonding, [39][40][41][42] and synergistic interactions 17,43,44 that can be integrated in experiments, simulations of SFGMs with a wide range of interface interaction were performed by modifying the Lennard-Jones potential well of AIREBO potential (ϵ). To modulate the interface interaction of SFGMs, the value of ϵ is modified as 1-30 times of the pristine value (ϵ 0 ), corresponding to the interlayer shear moduli of 0.32-10.62 GPa benchmarked in Supplementary Fig.…”

Section: Effect Of Interface Interaction On the Mechanical Behaviors mentioning

confidence: 99%

“…[18][19][20][21][22][23][24][25][26][27][28][29][30][31] For example, Zhang et al 30 prepared graphene films with a tensile strength of 453 MPa by modifying the chemical structures of graphene building blocks. The second strategy is interfacial engineering, including hydrogen bonding, 32 ionic bonding, [33][34][35] π-π bonding, [36][37][38] covalent bonding, [39][40][41][42] and synergistic interactions, 17,43,44 which can be integrated into the graphene-based materials and thus enable the efficient load transfer among the building blocks. For example, Wan et al 44 fabricated graphene films with a tensile strength of 945 MPa by successive application of the optimized ratio of π-π bonding and covalent bonding agents.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Bio-inspired self-folding strategy to break the trade-off between strength and ductility in carbon-nanoarchitected materials

2020

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Graphene possesses extraordinary mechanical, electronic, and thermal properties, thus making it one of the most promising building blocks for constructing macroscopic high performance and multifunctional materials. However, the common material strength-ductility paradox also appears in the carbon-nanoarchitected materials and some of the key mechanical performance, for example, the tensile strength of graphene-based materials, are still far lower than that of graphene. Inspired by the exceptional mechanical performance of silk protein benefiting from the conformations of folded structures as well as their transitions, this work proposed a topological strategy to yield graphene-based materials with ultrahigh ductility while maintaining decent tensile strength by self-folding graphene sheets. This drastically improved mechanical performance of graphene-based materials is attributed to the exploitation of shearing, sliding, and unfolding deformation at the self-folded interface. Molecular dynamics simulations show that both modulating self-folded length and engineering interface interaction can effectively control the strength, ductility, and the ductile failure of van der Waals interfaces among the self-folded structures, where interfacial shearing, sliding, and unfolding open channels to dissipate mechanical energy. Based on the insights into the atomic-scale deformation by molecular dynamics simulations, the underlying mechanism of deformation and failure of these materials is finally discussed with a continuum mechanics-based model. Our findings bring perceptive insights into the microstructure design of strong-yet-ductile materials for load-bearing engineering applications.

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Section: Effect Of Interface Interaction On the Mechanical Behaviors mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Bio-inspired self-folding strategy to break the trade-off between strength and ductility in carbon-nanoarchitected materials

2020

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“…In engineering material designs, the ductile and damagetolerant materials can be achieved by creating metastructures [7,8], designing nanocomposites [9][10][11][12][13] or directly printing layered/patterned 3D architectures [14][15][16][17]. However, these employed techniques, such as laser cutting, vacuum filtration, self-assembly, or 3D-printing, require the materials to have large enough sizes or to withstand violent processing.…”

Section: Introductionmentioning

confidence: 99%

Nanofibril Organization in Silk Fiber as Inspiration for Ductile and Damage-Tolerant Fiber Design

Lin

Zhang

et al. 2019

Adv. Fiber Mater.

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Ductile and damage-tolerant fibers (DDTFs) are desired in aerospace engineering, mechanical engineering, and biomedical engineering because of their ability to prevent the catastrophic sudden structural/mechanical failure. However, in practice, design and fabrication of DDTFs remain a major challenge due to finite fiber size and limited processing techniques. In this regard, animal silks can provide inspirations. They are hierarchically structured protein fibers with an elegant trade-off of mechanical strength, extensibility and damage tolerance, making them one of the toughest materials known. In this article, we confirmed that nanofibril organization could improve the ductility and damage-tolerance of silk fibers through restricted fibril shearing, controlled slippage and cleavage. Inspired by these strategies, we further established a rational strategy to produce polyamide DDTFs by combining electrospinning and yarn-spinning techniques. The resultant polymeric DDTFs show a silklike fracture resistance behavior, indicating potential applications in smart textile, biomedicine, and mechanical engineering.

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“…Second, Wan et al 4 demonstrate that reduced graphene oxide (rGO) nanosheets can be bridged by a type of highly p-conjugated long-chain polymer. The resulting p-bridged rGO films exhibit not only superb mechanical properties including tensile strength and toughness, but also extraordinary electrical properties, such as conductivity and electromagnetic interference shielding effectiveness, in comparison with untreated rGO films.…”

mentioning

confidence: 99%

“…This mechanism is analogous to the tension-shear chain model of mineral-protein composites observed in some biomaterials. 5 The design approaches used in Soler-Crespo et al 3 and Wan et al 4 offer insightful applications of the paradigm to create functional diversity out of simple building blocks. Using hierarchical arrangements to realize new functions has the potential to greatly advance the usefulness of widely abundant graphene materials and design new exquisite functionality into them.…”

mentioning

confidence: 99%