Mechanical properties of ultrahigh-strength gold nanowires

Wu, Bin; Heidelberg, Andreas; Boland, John J.

doi:10.1038/nmat1403

Cited by 881 publications

(706 citation statements)

References 28 publications

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“…the magnitude of compressive yield stress decreases as the nanowire width increase. These size effect trends are in good agreement with the experimental reports in the literature [25], in which the diameterdependent yield stress of gold nanowires with size ranging from 40 to 200 nm measured by means of bending experiments was reported [25]. The yield stresses of Ni nanowires reported here are substantially greater than that of bulk Ni, but close to the theoretical stress, which is 30 GPa from experiments [26].…”

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confidence: 91%

Alternating starvation of dislocations during plastic yielding in metallic nanowires

2008

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Using molecular dynamics simulations, we show that the mechanical deformation behaviors of single-crystalline nickel nanowires are quite different from their bulk counterparts. Correlation between the obtained stress-strain curves and the visualized defect evolution during deformation processes clearly demonstrates that a sequence of complex dislocation slip events results in a state of dislocation starvation, involving the nucleation and propagation of dislocations until they finally escape from the wires, so that the wires deform elastically until new dislocations are generated. Ó 2008 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved. Due to the unique mechanical, thermal, electrical and optical properties, materials with nanometer-sized structure have attracted a great deal of interest as potential building blocks in nanoelectronic and nanoelectromechanical devices [1]. Many researchers have demonstrated, through both experiments and analysis, that the structure and properties of nanowires can be quite different from those of bulk materials due to the effect of the large surface to volume ratio [2][3][4][5][6][7][8][9][10][11][12][13][14].Recently, Uchic et al. [15,16] and Greer et al. [17,18] reported that the plastic deformation behavior of single-crystalline sub-micropillars is dependent on the size of the pillar, even without a deformation gradient. More recently, a ''mechanical annealing" test was used to demonstrate that dislocations can be swept out of the samples through the progressive activation and exhaustion of dislocation sources [19]. These promising results raise an important question: is the size effect still operative when the size of the pillar is reduced to under 10 nanometers?Despite many efforts [6][7][8][9][10][11][12][13][14], a quantitative understanding of dislocation flow in nanoscale metals has remained elusive. In particular, the correlation of the dislocation flow with the stress-strain curve is of great interest, for the underlying mechanisms are typically represented by a mechanical response in macroscopic level experiments. An understanding of the post-yielding deformation mechanism is also of paramount importance. However, previous simulations have concentrated on the initial yielding behavior of metallic nanowires [9][10][11], while studies on the post-yielding are still lacking.It is well-known that most conventional bulk metals only have their initial yield point represented by the stress-strain curve, their plastic flow being characterized as continuous dislocation movement after yielding. Here we show, by using molecular dynamics simulations, that metallic nanowires behave in an alternating dislocation starvation manner upon uniaxial compressive loading, which involves dislocation nucleation from free surfaces, dislocation travel across to the opposite side and then escape out of the wire system, so that continued elastic deformation is required to nucleate new dislocations.We focus mainly on Ni[1 1 1] nanowires with a nearly square cross-section. Nanow...

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confidence: 91%

Alternating starvation of dislocations during plastic yielding in metallic nanowires

2008

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“…For all the experiments carried out with this setup, the distance between the needle and the collector was set at Solutions were electrospun for a very short time (~45 s), resulting in a low density mesh of fibers with radii between 20 and 40 nm. Mechanical measurements were performed following a technique previously developed for metallic and semiconducting wires (25)(26)(27). Scanning electron microscopy was used to monitor both the density and the position/alignment of the nanofibers across the trenches.…”

Section: Methodsmentioning

confidence: 99%

“…Scanning electron microscopy was used to monitor both the density and the position/alignment of the nanofibers across the trenches. Fibers spanning the trenches perpendicularly were pinned down by electron beam induced deposition of platinum inside a scanning electron microscope chamber (25) as shown on Figure 1A. Both the diameter and suspended length were measured for all fibers using an atomic force microscope (AFM).…”

Section: Methodsmentioning

confidence: 99%

Mechanical properties of individual electrospun polymer-nanotube composite nanofibers

Almecija

Blond

Sader

et al. 2009

Carbon

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“…It scales as j / h 2/3 h. [22] For our case, a gold film (Y gold % 78 GPa) on a PS substrate (Y PS % 3.5 GPa), we anticipate h ¼ Y gold /Y PS % 22.3. [23,24] To verify the theoretical predictions, we varied the thickness of deposited gold from 10 nm to 50 nm. This caused a shift of hundreds of nanometers in the wavelength distributions (Fig.…”

mentioning

confidence: 99%

“…[25] For example, yield strengths of gold nanowires (3-6 GPa) are much greater than that of the bulk (55-200 MPa). [23] In particular, for metallic nanofilms on polymer substrates, most groups have found that the yield stress scales inversely with the film thickness, with the most recently measured yield stress value for a 50 nm gold film (which happens to be our highest film thickness) on PS substrates being as high as 30 GPa. [26] Thus, for the film thicknesses we use, our peak stresses are clearly well below the yield point -which means that predictions from linear elasticity theory are appropriate.…”

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confidence: 99%

Tunable Nanowrinkles on Shape Memory Polymer Sheets

et al. 2009

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Controllable biaxial and uniaxial nanowrinkles (see figure) are fabricated by a simple two‐step approach — metal deposition and subsequent heating — based on shape memory polymer (prestressed polystyrene) sheets. The wavelengths of the wrinkles can be tuned by controlling the thickness of deposited metal. The ready integration of the nanowrinkles into microchannels and their effectiveness in surface enhanced sensing is demonstrated.

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Mechanical properties of ultrahigh-strength gold nanowires

Cited by 881 publications

References 28 publications

Alternating starvation of dislocations during plastic yielding in metallic nanowires

Alternating starvation of dislocations during plastic yielding in metallic nanowires

Mechanical properties of individual electrospun polymer-nanotube composite nanofibers

Tunable Nanowrinkles on Shape Memory Polymer Sheets

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