SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W3193146280> ?p ?o ?g. }

Showing items 1 to 100 of ±173 with 100 items per page.

W3193146280 endingPage "106" @default.
W3193146280 startingPage "95" @default.
W3193146280 abstract "Nanocrystalline metals often display a high strength up to the gigapascal level, yet they suffer from poor plasticity. Previous studies have shown that the development of hetero-sized grains can efficiently overcome the strength-ductility trade-off of nanocrystalline metals. However, whether this strategy can lead to the fabrication of nanocrystalline nanowires exhibiting both high strength and superplasticity is unclear, similar to the atomistic deformation mechanism. In this paper, we show that ultra-small nanocrystalline Au nanowires comprising grains in both the Hall–Petch and inverse Hall–Petch grain-size regions can exhibit extremely high uniform elongation (236%) and high strength (2.34 gigapascals) at room temperature. In situ atomic-scale observations revealed that the plastic deformation underwent two stages. In the first stage, the super-elongation ability originated from the intergrain plasticity of small grains via mechanisms such as grain boundary migration and grain rotation. This intergrain plasticity caused the grains in the heterogeneous-structured nanowires to grow very large. In the second stage, the super-elongation ability originated from intragrain plasticity accompanied by the diffusion of surface atoms. Our results show that the hetero-grain-sized nanocrystalline nanowires, comprising grains with sizes both in the strongest Hall–Petch effect region and the inverse Hall–Petch effect region, were simultaneously ultra-strong and ductile. They displayed neither a strength-ductility trade-off nor plastic instability." @default.
W3193146280 created "2021-08-16" @default.
W3193146280 creator A5006111469 @default.
W3193146280 creator A5008654388 @default.
W3193146280 creator A5020674586 @default.
W3193146280 creator A5029673797 @default.
W3193146280 creator A5034746502 @default.
W3193146280 creator A5038339911 @default.
W3193146280 creator A5040215906 @default.
W3193146280 creator A5042617388 @default.
W3193146280 creator A5055817822 @default.
W3193146280 creator A5061576274 @default.
W3193146280 creator A5063731792 @default.
W3193146280 creator A5079645279 @default.
W3193146280 creator A5083344602 @default.
W3193146280 date "2022-02-01" @default.
W3193146280 modified "2023-10-18" @default.
W3193146280 title "Ultra-high strength yet superplasticity in a hetero-grain-sized nanocrystalline Au nanowire" @default.
W3193146280 cites W1576114465 @default.
W3193146280 cites W1673476633 @default.
W3193146280 cites W1968241153 @default.
W3193146280 cites W1975102277 @default.
W3193146280 cites W1983543277 @default.
W3193146280 cites W1987313819 @default.
W3193146280 cites W1990026139 @default.
W3193146280 cites W1993767215 @default.
W3193146280 cites W1999938229 @default.
W3193146280 cites W2003746161 @default.
W3193146280 cites W2009724607 @default.
W3193146280 cites W2010231017 @default.
W3193146280 cites W2012119282 @default.
W3193146280 cites W2012615024 @default.
W3193146280 cites W2019465613 @default.
W3193146280 cites W2021707244 @default.
W3193146280 cites W2031245616 @default.
W3193146280 cites W2040828793 @default.
W3193146280 cites W2047553514 @default.
W3193146280 cites W2048528541 @default.
W3193146280 cites W2052137108 @default.
W3193146280 cites W2052538097 @default.
W3193146280 cites W2055302323 @default.
W3193146280 cites W2057712666 @default.
W3193146280 cites W2059300796 @default.
W3193146280 cites W2061911959 @default.
W3193146280 cites W2069416742 @default.
W3193146280 cites W2073186484 @default.
W3193146280 cites W2090370895 @default.
W3193146280 cites W2099518258 @default.
W3193146280 cites W2120805857 @default.
W3193146280 cites W2132482694 @default.
W3193146280 cites W2143867693 @default.
W3193146280 cites W2155738607 @default.
W3193146280 cites W2163982872 @default.
W3193146280 cites W2165754909 @default.
W3193146280 cites W2298529479 @default.
W3193146280 cites W2315574782 @default.
W3193146280 cites W2326773168 @default.
W3193146280 cites W2395401698 @default.
W3193146280 cites W2413768027 @default.
W3193146280 cites W2478819728 @default.
W3193146280 cites W2518691405 @default.
W3193146280 cites W2558989842 @default.
W3193146280 cites W2601358472 @default.
W3193146280 cites W2605773392 @default.
W3193146280 cites W2610728229 @default.
W3193146280 cites W2736208352 @default.
W3193146280 cites W2781915916 @default.
W3193146280 cites W2790326054 @default.
W3193146280 cites W2792707842 @default.
W3193146280 cites W2792964017 @default.
W3193146280 cites W2794700432 @default.
W3193146280 cites W2795341196 @default.
W3193146280 cites W2801705522 @default.
W3193146280 cites W2884141873 @default.
W3193146280 cites W2887995807 @default.
W3193146280 cites W2890852863 @default.
W3193146280 cites W2890914297 @default.
W3193146280 cites W2892854167 @default.
W3193146280 cites W2896718190 @default.
W3193146280 cites W2897625699 @default.
W3193146280 cites W2900812253 @default.
W3193146280 cites W2901546241 @default.
W3193146280 cites W2908958579 @default.
W3193146280 cites W2937269856 @default.
W3193146280 cites W2959676883 @default.
W3193146280 cites W2960900102 @default.
W3193146280 cites W2988351346 @default.
W3193146280 cites W3000131637 @default.
W3193146280 cites W3004778657 @default.
W3193146280 cites W3025328126 @default.
W3193146280 cites W3091616351 @default.
W3193146280 cites W3127369175 @default.
W3193146280 cites W4254466070 @default.
W3193146280 doi "https://doi.org/10.1016/j.jmst.2021.05.063" @default.
W3193146280 hasPublicationYear "2022" @default.
W3193146280 type Work @default.
W3193146280 sameAs 3193146280 @default.
W3193146280 citedByCount "9" @default.