Xiaoguang Guo scite author profile

Nanowires (NWs) have been envisioned as building blocks of nanotechnology and nanodevices. In this study, NWs were manipulated using a weasel hair, and fixed by conductive silver epoxy, eliminating the contaminations and damages induced by conventional beam depositions. The fracture strength of the amorphous silicon carbide was found to be 8.8 GPa, which was measured by in situ transmission electron microscopy nanomechanical testing, approaching the theoretical fracture limit. Here, we report that self-healing of mismatched fractured amorphous surfaces of brittle NWs was discovered. The fracture strength was found to be 5.6 GPa on the mismatched fractured surfaces, recovering 63.6% of that of pristine NWs. This is an ultrahigh recovery, due to the limits of reconstruction of dangling bonds on the fractured amorphous surfaces and the mismatched areas. Simulation by molecular dynamics showed fracture strength recovery of 65.9% on the mismatched fractured amorphous surfaces, which is in good agreement with the experimental results. Healing on the mismatched fractured amorphous surfaces is by reorganization of Si-C bonds forming Si-C and Si-Si bonds. The potential energy increases 2.6 eV in the reorganized Si-C bonds, and decreases by 3.2 and 1.9 eV, respectively, in the formed Si-C and Si-2 Si bonds. These findings provide insights for the reliability, design and fabrication of high performance NW-based devices, to avoid catastrophic failure working in harsh and extreme environments.

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A New Approach to Track Multiple Vehicles With the Combination of Robust Detection and Two Classifiers

Min

Fan

Guo

et al. 2018

IEEE Trans. Intell. Transport. Syst.

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Atomistic mechanisms of chemical mechanical polishing of diamond (1 0 0) in aqueous H2O2/pure H2O: Molecular dynamics simulations using reactive force field (ReaxFF)

Guo

Yuan

Wang

et al. 2019

Computational Materials Science

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Effects of pressure and slurry on removal mechanism during the chemical mechanical polishing of quartz glass using ReaxFF MD

Guo

Yuan

Huang

et al. 2020

Applied Surface Science

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Xiaoguang Guo

Augmented reality navigation for liver resection with a stereoscopic laparoscope

Ultrahigh Recovery of Fracture Strength on Mismatched Fractured Amorphous Surfaces of Silicon Carbide

A New Approach to Track Multiple Vehicles With the Combination of Robust Detection and Two Classifiers

Atomistic mechanisms of chemical mechanical polishing of diamond (1 0 0) in aqueous H2O2/pure H2O: Molecular dynamics simulations using reactive force field (ReaxFF)

Effects of pressure and slurry on removal mechanism during the chemical mechanical polishing of quartz glass using ReaxFF MD

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Xiaoguang Guo

Augmented reality navigation for liver resection with a stereoscopic laparoscope

Ultrahigh Recovery of Fracture Strength on Mismatched Fractured Amorphous Surfaces of Silicon Carbide

A New Approach to Track Multiple Vehicles With the Combination of Robust Detection and Two Classifiers

Atomistic mechanisms of chemical mechanical polishing of diamond (1 0 0) in aqueous H2O2/pure H2O: Molecular dynamics simulations using reactive force field (ReaxFF)

Effects of pressure and slurry on removal mechanism during the chemical mechanical polishing of quartz glass using ReaxFF MD

Contact Info

Product

Resources

About

Atomistic mechanisms of chemical mechanical polishing of diamond (1 0 0) in aqueous H2O2/pure H2O: Molecular dynamics simulations using reactive force field (ReaxFF)