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Literature DB >> 27798834

Fluid-like Surface Layer and Its Flow Characteristics in Glassy Nanotubes.

Matthew C Wingert¹, Soonshin Kwon¹, Shengqiang Cai¹, Renkun Chen¹.

Abstract

We show that amorphous silica and Si nanotubes can flow at room temperature under Giga-Pascal order stress when going to the nanometer scale. This creep behavior is unique for the amorphous nanotubes and is absent in crystalline Si nanotubes of similar dimensions. A core-shell model shows that there exists an approximately 1 nm thick viscoelastic "fluid-like" surface layer, which exhibits a room temperature viscosity equivalent to that of bulk glass above 1000 °C.

Entities: Chemical

Keywords: Glass transition; core-shell model; creep strain; silica nanotube; silicon nanotube; viscoelasticity

Year: 2016 PMID： 27798834 DOI： 10.1021/acs.nanolett.6b03377

Source DB: PubMed Journal: Nano Lett ISSN： 1530-6984 Impact factor: 11.189

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Cited

1 in total

1. Electron beam-induced athermal nanowelding of crossing SiO _x amorphous nanowires.

Authors: Yuchen Zheng; Liang Cheng; Jiangbin Su; Chuncai Chen; Xianfang Zhu; Hang Li
Journal: RSC Adv Date: 2022-02-21 Impact factor: 3.361

1 in total

Fluid-like Surface Layer and Its Flow Characteristics in Glassy Nanotubes.

1. Electron beam-induced athermal nanowelding of crossing SiO x amorphous nanowires.

1. Electron beam-induced athermal nanowelding of crossing SiO _x amorphous nanowires.