Chenlong Xie scite author profile

Chenlong Xie

5Publications

88Citation Statements Received

0Citation Statements Given

How they've been cited

110

How they cite others

232

Affiliations

Yanshan University, SGIDI Engineering Consulting (China)

Publications

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Mechanical properties of boron arsenide single crystal

Tian

Luo

Xie

et al. 2019

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As the only semiconductor material exhibiting ultrahigh thermal conductivity under ambient conditions, cubic boron arsenide (BAs) is currently attracting great interest. Thanks to the development of high-quality BAs single crystal growth techniques, investigation of its basic physical properties has now become possible. Here, the mechanical properties of BAs single crystals are studied by experimental measurements combined with first-principles calculations. A Vickers hardness of 22 GPa suggests that BAs is a hard material, although not among the hardest. The bulk and Young's moduli are measured to be 142 and 388 GPa, respectively. These important mechanical performance parameters, in conjunction with the unusual high thermal conductivity, show great potential for BAs to serve in next-generation semiconductor applications.

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Superhard three-dimensional B₃N₄ with two-dimensional metallicity

Xie

Liu

et al. 2017

J. Mater. Chem. C

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Restacked melon as highly-efficient photocatalyst

Wang

Zhang

et al. 2020

Nano Energy

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A superhard sp3 microporous carbon with direct bandgap

Pan

Xie

Xiong

et al. 2017

Chemical Physics Letters

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Hard nanocrystalline gold materials prepared via high-pressure phase transformation

Xie

Niu

et al. 2022

Nano Res.

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As one of the important materials, nanocrystalline Au (n-Au) has gained numerous interests in recent decades owing to its unique properties and promising applications. However, most of the current n-Au thin films are supported on substrates, limiting the study on their mechanical properties and applications. Therefore, it is urgently desired to develop a new strategy to prepare n-Au materials with superior mechanical strength and hardness. Here, a hard n-Au material with an average grain size of ~ 40 nm is prepared by cold-forging of the unique Au nanoribbons (NRBs) with unconventional 4H phase under high pressure. Systematic characterizations reveal the phase transformation from 4H to face-centered cubic (fcc) phase during the cold compression. Impressively, the compressive yield strength and Vickers hardness (H V ) of the prepared n-Au material reach ~ 140.2 MPa and ~ 1.0 GPa, which are 4.2 and 2.2 times of the microcrystalline Au foil, respectively. This work demonstrates that the combination of high-pressure cold-forging and the in-situ 4H-to-fcc phase transformation can effectively inhibit the grain growth in the obtained n-Au materials, leading to the formation of novel hard n-Au materials. Our strategy opens up a new avenue for the preparation of nanocrystalline metals with superior mechanical property.nanocrystalline Au, high hardness, high strength, high-pressure forging, 4H Au nanoribbons

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Chenlong Xie

Mechanical properties of boron arsenide single crystal

Superhard three-dimensional B₃N₄ with two-dimensional metallicity

Restacked melon as highly-efficient photocatalyst

A superhard sp3 microporous carbon with direct bandgap

Hard nanocrystalline gold materials prepared via high-pressure phase transformation

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Chenlong Xie

Mechanical properties of boron arsenide single crystal

Superhard three-dimensional B3N4 with two-dimensional metallicity

Restacked melon as highly-efficient photocatalyst

A superhard sp3 microporous carbon with direct bandgap

Hard nanocrystalline gold materials prepared via high-pressure phase transformation

Contact Info

Product

Resources

About

Superhard three-dimensional B₃N₄ with two-dimensional metallicity