Atomistic perspective on in situ nanomechanics

Wang, Jiangwei; Mao, Scott X.

doi:10.1016/j.eml.2016.02.006

Cited by 32 publications

(15 citation statements)

References 152 publications

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“…Similar to the method to create thin NWs in the AFM force spectroscopy, thin metal NWs were formed with stable contacts between a metal rod and a scanning tunneling microscope (STM) probe inside TEM, especially under applied voltage [107,108]. Stable contacts can also form between thin metal NWs inside TEM by cold welding [109].…”

Section: Tensionmentioning

confidence: 99%

Mechanics of Crystalline Nanowires: An Experimental Perspective

Zhu

2017

Applied Mechanics Reviews

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A wide variety of crystalline nanowires (NWs) with outstanding mechanical properties have recently emerged. Measuring their mechanical properties and understanding their deformation mechanisms are of important relevance to many of their device applications. On the other hand, such crystalline NWs can provide an unprecedented platform for probing mechanics at the nanoscale. While challenging, the field of experimental mechanics of crystalline nanowires has emerged and seen exciting progress in the past decade. This review summarizes recent advances in this field, focusing on major experimental methods using atomic force microscope (AFM) and electron microscopes and key results on mechanics of crystalline nanowires learned from such experimental studies. Advances in several selected topics are discussed including elasticity, fracture, plasticity, and anelasticity. Finally, this review surveys some applications of crystalline nanowires such as flexible and stretchable electronics, nanocomposites, nanoelectromechanical systems (NEMS), energy harvesting and storage, and strain engineering, where mechanics plays a key role.

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Section: Tensionmentioning

confidence: 99%

Mechanics of Crystalline Nanowires: An Experimental Perspective

Zhu

2017

Applied Mechanics Reviews

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“…Some experimental insights into the GB migration have been obtained in the past two decades, with the spring up of well-designed in situ transmission electron microscopy (TEM) techniques 10,20,21 . For example, in situ heating experiments have revealed a thermal-induced GB migration in Au and Al thin films at 0.4–0.7 T m ( T m is the melting temperature) through the atomic shuffling 22 or GB disconnection 23 mechanisms.…”

Section: Introductionmentioning

confidence: 99%

In situ atomistic observation of disconnection-mediated grain boundary migration

et al. 2019

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Shear-coupled grain boundary (GB) migration is of general significance in the deformation of nanocrystalline and polycrystalline materials, but comprehensive understanding of the migration mechanism at the atomic scale remains largely lacking. Here, we systematically investigate the atomistic migration of Σ11(113) coherent GBs in gold bicrystals using a state-of-art in situ shear testing technique combined with molecular dynamic simulations. We show that shear-coupled GB migration can be realised by the lateral motion of layer-by-layer nucleated GB disconnections, where both single-layer and double-layer disconnections have important contributions to the GB migration through their frequent composition and decomposition. We further demonstrate that the disconnection-mediated GB migration is fully reversible in shear loading cycles. Such disconnection-mediated GB migration should represent a general deformation phenomenon in GBs with different structures in polycrystalline and nanocrystalline materials, where the triple junctions can act as effective nucleation sites of GB disconnections.

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“…All these studies have shown that the important mechanisms of plastic deformation in FCC nanowires are slip through perfect and partial dislocations and deformation twinning. The competition between slip and twinning mechanisms depends mainly on the crystallographic orientation, size, shape and loading mode (tension/compression), temperature and strain rate [13,14,15]. However, among all these factors, crystallographic orientation has the strongest influence followed by mode of loading [12,13].…”

Section: Introductionmentioning

confidence: 99%

Effect of orientation and mode of loading on deformation behaviour of Cu nanowires

Rohith

Sainath

Choudhary

2018

Computational Condensed Matter

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Molecular dynamics simulations have been performed to understand the variations in deformation mechanisms of Cu nanowires as a function of orientation and loading mode (tension or compression). Cu nanowires of different crystallographic orientations distributed uniformly on the standard stereographic triangle have been considered under tensile and compressive loading. The simulation results indicate that under compressive loading, the orientations close to <100> corner deform by twinning mechanism, while the remaining orientations deform by dislocation slip. On the other hand, all the nanowires deform by twinning mechanism under tensile loading. Further, the orientations close to <110> and <111> corner exhibit tensioncompression asymmetry in deformation mechanisms. In addition to deformation mechanisms, Cu nanowires also display tension-compression asymmetry in yield stress. The orientations close to <001> corner exhibits higher yield stress in tension than in compression, while the opposite behaviour (higher yield stress in compression than in tension) has been observed in orientations close to <110> and <111> corners. For the specific orientation of <102>, the yield stress asymmetry has not been observed. The tension-compression asymmetry in deformation mechanisms has been explained based on the parameter α M , defined as the ratio of Schmid factors for leading and trailing partial dislocations. Similarly, the asymmetry in yield stress values has been attributed to the different Schmid factor values for leading partial dislocations under tensile and compressive loading.

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Atomistic perspective on in situ nanomechanics

Cited by 32 publications

References 152 publications

Mechanics of Crystalline Nanowires: An Experimental Perspective

Mechanics of Crystalline Nanowires: An Experimental Perspective

In situ atomistic observation of disconnection-mediated grain boundary migration

Effect of orientation and mode of loading on deformation behaviour of Cu nanowires

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