Suspended monolayer graphene traps high-speed single-walled carbon nanotube

“…In previous studies, the out-of-plane displacement of special atoms and snapshots of MD simulations for PG and defective graphene are presented to study the evolution of dynamic wrinkle propagation, which are proved to be valid. 14–16,50 To investigate the evolution of dynamic wrinkle propagation in graphene with tilt GBs, seven carbon atoms (atom-a, atom-b, atom-c, atom-d, atom-e, atom-f, and atom-g), one atomic line (L GB ) and two atomic regions (R GB and R 80 ) are marked in Fig. 2.…”

“…12 The impact dynamic mechanical behavior of graphene has been studied intensively, especially for dynamic wrinkle propagation and the ballistic performance of graphene. [12][13][14][15][16][17] Moreover, extensive studies have been conducted to investigate dynamic wrinkle propagation, such as anisotropic wave propagation, 18,19 transverse wave propagation, [19][20][21] bucklingdriven wrinkles, [22][23][24][25] and dynamic ripple pattern regulation 26,27 in graphene. With the development of synthetic processes, the production of large-area graphene can be realized via chemical vapor deposition (CVD), 28,29 thermal graphitization, 30 and liquidphase exfoliation.…”

Anomalous wrinkle propagation in polycrystalline graphene with tilt grain boundaries

“…In previous studies, the out-of-plane displacement of special atoms and snapshots of MD simulations for PG and defective graphene are presented to study the evolution of dynamic wrinkle propagation, which are proved to be valid. 14–16,50 To investigate the evolution of dynamic wrinkle propagation in graphene with tilt GBs, seven carbon atoms (atom-a, atom-b, atom-c, atom-d, atom-e, atom-f, and atom-g), one atomic line (L GB ) and two atomic regions (R GB and R 80 ) are marked in Fig. 2.…”

“…12 The impact dynamic mechanical behavior of graphene has been studied intensively, especially for dynamic wrinkle propagation and the ballistic performance of graphene. [12][13][14][15][16][17] Moreover, extensive studies have been conducted to investigate dynamic wrinkle propagation, such as anisotropic wave propagation, 18,19 transverse wave propagation, [19][20][21] bucklingdriven wrinkles, [22][23][24][25] and dynamic ripple pattern regulation 26,27 in graphene. With the development of synthetic processes, the production of large-area graphene can be realized via chemical vapor deposition (CVD), 28,29 thermal graphitization, 30 and liquidphase exfoliation.…”

Anomalous wrinkle propagation in polycrystalline graphene with tilt grain boundaries

“…Pure carbon architectures, such as carbon nanotubes [12][13][14] and graphene [15,16], not only have high surface area and excellent conductivity but also exhibit intensive absorption at GHz level [17][18][19]. However, the absorption bandwidth of these carbon architectures cannot be satisfied due to the absence of magnetic loss [20].…”

In-situ growth of Fe/Fe3O4/C hierarchical architectures with wide-band electromagnetic wave absorption

“…However, the rapidly increasing strain characteristics of impact events can lead to stress localization and fractures 9 , thus possibly affecting their mechanical performance. Recently, many works have been dedicated to the mechanical characterization of nanostructures in the high strain-rate regime 10,11,12,13,14,15 , including the observation of record-breaking energy absorption capabilities for graphene-based materials 9 .…”

“…However, the rapidly increasing strain characteristic of impact events can lead to stress localization and fractures, 9 possibly affecting mechanical performance. Recently, many studies have been dedicated to the mechanical characterization of nanostructures in the high strain-rate regime, [10][11][12][13][14][15] including the observation of record-breaking energy absorption capabilities for graphenebased materials. 9 In order to generate high strain-rate conditions, a typical procedure is to shoot projectiles against stationary nanostructures or, vice versa, shooting nanomaterials against stationary targets.…”

Structural transformations of carbon and boron nitride nanoscrolls at high impact collisions