History-independent cyclic response of nanotwinned metals

Pan, Qingsong; Zhou, Haofei; Lu, Qian; Gao, Huajian; Lü, Lei

doi:10.1038/nature24266

Cited by 212 publications

(82 citation statements)

References 46 publications

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“…Metallic materials with a high tensile strength might have a low-fatigue lifetime. However, the nanotwinned Cu films have been demonstrated to have high-fatigue resistance [8]. In addition, Li et al also reported nanotwinned Cu redistribution lines possess high-fatigue resistance to temperature cycling tests [20].…”

Section: Resultsmentioning

confidence: 99%

“…In recent years, nanotwinned copper (nt-Cu) was found to have high strength, ideal ductility, excellent thermal stability, low resistivity [4,5], high electromigration resistance [6], and history-independent cyclic response during fatigue tests [7,8]. Generally, magnetron sputtering and electroplating have been applied in fabricating highly <111>-oriented nt-Cu.…”

Section: Introductionmentioning

confidence: 99%

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Tensile Properties and Thermal Stability of Unidirectionally <111>-Oriented Nanotwinned and <110>-Oriented Microtwinned Copper

Chen

2020

Materials

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Tensile tests on two kinds of electroplated copper foils with twins before and after annealing were performed. One electroplating parameter results in a microstructure of <110>-oriented microtwinned Cu (mt-Cu), and the other is <111>-oriented nanotwinned Cu (nt-Cu). The latter shows higher thermal stability than the former after annealing. Though the toughness for the two as-plated foils are quite close, the toughness for the <111> oriented nt-Cu increased from 34 to 74 MJ/m 3 after annealing at 250 • C for 3 h. In comparison, the toughness of the <110>-oriented mt-Cu remained almost the same after annealing.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tensile Properties and Thermal Stability of Unidirectionally <111>-Oriented Nanotwinned and <110>-Oriented Microtwinned Copper

Chen

2020

Materials

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“…Thus, due to the similar size and uniform distribution of α phase, FLM with nanoscale α phase possesses super resistance against fatigue crack initiation than BM. Moreover, Pan et al [36] has found that the dislocations move collectively back and forth along the nanotwins during cyclic loading, which indicated that nanotwins promotes the reversible dislocation slip and increases the fatigue life. Whereas, cyclic plastic deformation is produced at each cycle during low cycle fatigue.…”

Section: Cracks Propagationmentioning

confidence: 99%

Effect of size of alpha phases on cyclic deformation and fatigue crack initiation during fatigue of an alpha-beta titanium alloy

et al. 2018

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Abstract. Alpha phase exhibits equiaxed or lamellar morphologies with size from submicron to microns in an alpha-beta titanium alloy. Cyclic deformation, slip characteristics and crack nucleation during fatigue in different microstructures of TC21 alloy (Ti-6Al-2Sn-2Zr-3Mo-1Cr-2Nb-0.1Si) were systematically investigated and analyzed. During low-cycle fatigue, equiaxed microstructure (EM) in TC21 alloy exhibits higher strength, ductility and longer low-cycle fatigue life than those of the lamellar microstructure (LM). There are more voids in the single lamellar alpha than the equiaxed alpha grains. As a result, voids more easily link up to form crack in the lamellar alpha phase than the equiaxed alpha phase. However, during high-cycle fatigue, the fine lamellar microstructure (FLM) shows higher fatigue limit than bimodal microstructure (BM). The localized plastic deformation can be induced during high-cycle fatigue. The slip bands or twins are observed in the equiaxed and lamellar alpha phases( >1micron), which tends to form strain concentration and initiate fatigue crack. The localized slip within nanoscale alpha plates is seldom observed and extrusion/intrusion dispersedly distributed on the sample surface in FLM. This indicates that FLM show super resistance to fatigue crack which bring about higher fatigue limit than BM.

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“…As the extension of stacking faults, twin activities are highly related to partial dislocation activities. Moreover, studies revealed that the induced twins can enhance mechanical performances such as strength 88,89 , hardness 90,91 , fracture toughness 88,89 and anti-fatigue 92 .…”

Section: And Twins and Grain Boundariesmentioning

confidence: 99%

“…However, in-situ TEM observation studies by Wang et al 94,95 revealed that full dislocation activities are still existent in the deformation processes of nc-Pt thin films, even in the d~10nm Pt grains. Figure 2.1 are high-resolution (HR) TEM images that show the full dislocations nucleation and annihilation processes during the tensile deformation processes 92 . Grain A (d~12 nm) was monitored during the whole deformation processes, as labelled by white dash lines in Figure 2.1a.…”

Section: Dislocation-mediated and Twinning Mechanismsmentioning

confidence: 99%

In-situ nanoscale TEM observation of cooperative deformation mechanisms in nanocrystalline-Au films

Li¹

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Grain boundaries activities are important for the deformation of nanocrystalline metals.Studies revealed that deformation mechanisms of nanocrystalline metals switch from dislocation-mediated regime to grain-boundary-mediated regime as approaching the "strongest" grain size. Basically, stress-driven grain growth, grain rotation and grain boundary sliding have been widely studied and discussed in the aspect of grain-boundary-mediated deformation mechanisms in nanocrystalline metals. Based on the previous studies, these grain-boundarymediated deformation mechanisms could perform in either individual forms or cooperative forms. However, limited studies have been focused on the cooperative form mechanisms for the grain-boundary-mediated deformation mechanism, especially for the cooperative grain boundary sliding mechanisms which could lead to more ductile performance than the pure grain boundary sliding. Particularly, only a few molecular dynamic simulation studies and theoretical prediction studies investigated the cooperative grain boundary sliding mechanism in nanocrystalline metals. Therefore, it is necessary to practically examine the true deformation behaviours in straining nanocrystalline metals.In this MPhil project, with utilising the homemade tensile device equipped with a transmission electron microscopy heating holder, in-situ transmission electron microscopy tensile tests are conducted for the magnetic-sputtering-fabricated nanocrystalline Au thin films (thickness ~ 15nm, average grain size ~ 16nm). In the in-situ experiments, the dynamic crack propagation processes of strained nanocrystalline Au films are clearly recorded under nanoscale bright-field TEM mode. It has been found that grain boundary sliding and stress-driven grain boundary migration are prevalent during the deformation processes. As cooperative deformation mechanism, stress-driven grain boundary migration assisted grain boundary sliding is confirmed experimentally. It is also found that cooperative grain boundary sliding mechanism

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History-independent cyclic response of nanotwinned metals

Cited by 212 publications

References 46 publications

Tensile Properties and Thermal Stability of Unidirectionally <111>-Oriented Nanotwinned and <110>-Oriented Microtwinned Copper

Tensile Properties and Thermal Stability of Unidirectionally <111>-Oriented Nanotwinned and <110>-Oriented Microtwinned Copper

Effect of size of alpha phases on cyclic deformation and fatigue crack initiation during fatigue of an alpha-beta titanium alloy

In-situ nanoscale TEM observation of cooperative deformation mechanisms in nanocrystalline-Au films

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