Unzipping Carbon Nanotubes at High Impact

Özden, Şehmus; Autreto, Pedro Alves da Silva; Tiwary, Chandra Sekhar; Khatiwada, Suman; Machado, Leonardo D.; Galvão, Douglas S.; Vajtai, Róbert; Barrera, Enrique V.; Ajayan, Pulickel M.

doi:10.1021/nl501753n

Cited by 68 publications

(84 citation statements)

References 20 publications

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“…26b). This is consistent with the finding that high impact can unzip carbon nanotubes (Ozden et al 2014). Chew et al (2011) found that the com- Fig.…”

Section: With Permissionsupporting

confidence: 89%

Fracture of graphene: a review

2015

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Fracture is one of the most prominent concerns for large scale applications of graphene. In this paper, we review some of the recent progresses in experimental and theoretical studies on the fracture behaviors of graphene, with discussions touching theoretical strength, mode I fracture toughness, mixed mode fracture, chemical fracture, irradiation fracture, dynamic fracture, impact fracture, and sonication fracture. In spite of rapid developments in experiments and simulations, there are still significant yet unresolved issues related to the fracture of graphene, examples including: (1) Can one enhance the toughness of graphene with designed topological defects? (2) How does grain size affect the strength of polycrystalline graphene? (3) How do the out-of-plane effects (e.g., wrinkle caused by external loading or curvature induced by topological defects) influence the fracture of graphene? (4) Can one develop a continuum model with the ability to capture graphene fracture with complicated modes, such as shear fracture coupled with wrinkling deformation and tear fracture? (5) How does fracture occur when tearing a polycrystalline graphene sheet? (6) Can one control the fracture behavior of graphene by combing the chemical, irradiation and stress effect? (7) How fast can cracks propagate in graphene? (8) What is the behavior of interfacial cracks in graphene, i.e., cracks along the grain boundaries or interfaces of heterogeneous structures? (9) How does a multilayer graphene membrane break under high speed impact and why such structures can absorb a large amount of kinetic energy? (10) Can one tailor/design the graphene structures with controlled fracture? The intention here is not to provide complete answers to such questions, but to draw attention from the mechanics community to them as potential research topics.

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“…26b). This is consistent with the finding that high impact can unzip carbon nanotubes (Ozden et al 2014). Chew et al (2011) found that the com- Fig.…”

Section: With Permissionsupporting

confidence: 89%

Fracture of graphene: a review

2015

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“…Jiao et al and Kosynkin et al successfully employed this technique for the first time to prepare graphene nanosheets from MWCNTs 37,38 . Since then, many reports have appeared on the preparation of graphene nanosheets from MWCNTs [39][40][41][42][43] . Besides chemical unzipping, plasma, microwave, electrochemical, microwave and laser assisted unzipping methods have all been used to prepare graphene nanosheets [44][45][46][47] .…”

Section: Introductionmentioning

confidence: 99%

Recent developments in 2D layered inorganic nanomaterials for sensing

et al. 2015

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Two dimensional layered inorganic nanomaterials (2D-LINs) have recently attracted huge interest because of their unique thickness dependent physical and chemical properties and potential technological applications. The properties of these layered materials can be tuned via both physical and chemical processes. Some 2D layered inorganic nanomaterials like MoS2, WS2 and SnS2 have been recently developed and employed in various applications, including new sensors because of their layer-dependent electrical properties. This article presents a comprehensive overview of recent developments in the application of 2D layered inorganic nanomaterials as sensors. Some of the salient features of 2D materials for different sensing applications are discussed, including gas sensing, electrochemical sensing, SERS and biosensing, SERS sensing and photodetection. The working principles of the sensors are also discussed together with examples.

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“…In such kind of complex processes, the fracturing of C-C bonds along a particular direction needs high energy, which can be provided using high strain rate (10 8À10 /s) deformation [20][21][22][23]. In our previous work, we reported a combined experimental and theoretical study of CNTs under high velocity impact [24]. Such experiments give rise to one step chemical-free unzipping due to local concentration of stress at particular location of CNT [24].…”

Section: Introductionmentioning

confidence: 99%

“…In our previous work, we reported a combined experimental and theoretical study of CNTs under high velocity impact [24]. Such experiments give rise to one step chemical-free unzipping due to local concentration of stress at particular location of CNT [24]. Utilising this understanding, we used a cryo-milling machine designed by us (KC0, Tau Instrument, Bangalore, India) that can deform CNTs with a frequency of 50 Hz and displacement amplitude of 3 mm of the vibrating ball.…”

Section: Introductionmentioning

confidence: 99%