Origin of Plasticity in Nanostructured Silicon

Zhidan Zeng; Qiaoshi Zeng; Mingyuan Ge; Bin Chen; Hongbo Lou; Xiehang Chen; Jinyuan Yan; Wenge Yang; Ho Kwang Mao; Deren Yang; Wendy L. Mao

doi:10.1103/PhysRevLett.124.185701

Origin of Plasticity in Nanostructured Silicon

Zhidan Zeng
, Qiaoshi Zeng
, Mingyuan Ge
, Bin Chen
, Hongbo Lou
, Xiehang Chen
, Jinyuan Yan
, Wenge Yang
, Ho Kwang Mao
, Deren Yang
, Wendy L. Mao

Center for High Pressure Science & Technology Advanced Research
Southeast University, Nanjing
Brookhaven National Laboratory
Lawrence Berkeley National Laboratory
Zhejiang University
Stanford University
SLAC National Accelerator Laboratory

Research output: Contribution to journal › Article › peer-review

20 Scopus citations

Abstract

The mechanism of plasticity in nanostructured Si has been intensively studied over the past decade but still remains elusive. Here, we used in situ high-pressure radial x-ray diffraction to simultaneously monitor the deformation and structural evolution of a large number of randomly oriented Si nanoparticles (SiNPs). In contrast to the high-pressure β-Sn phase dominated plasticity observed in large SiNPs (∼100 nm), small SiNPs (∼9 nm) display a high-pressure simple hexagonal phase dominated plasticity. Meanwhile, dislocation activity exists in all of the phases, but significantly weakens as the particle size decreases and only leads to subtle plasticity in the initial diamond cubic phase. Furthermore, texture simulations identify major active slip systems in all of the phases. These findings elucidate the origin of plasticity in nanostructured Si under stress and provide key guidance for the application of nanostructured Si.

Original language	English
Article number	185701
Journal	Physical Review Letters
Volume	124
Issue number	18
DOIs	https://doi.org/10.1103/PhysRevLett.124.185701
State	Published - 8 May 2020
Externally published	Yes

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title = "Origin of Plasticity in Nanostructured Silicon",

abstract = "The mechanism of plasticity in nanostructured Si has been intensively studied over the past decade but still remains elusive. Here, we used in situ high-pressure radial x-ray diffraction to simultaneously monitor the deformation and structural evolution of a large number of randomly oriented Si nanoparticles (SiNPs). In contrast to the high-pressure β-Sn phase dominated plasticity observed in large SiNPs (∼100 nm), small SiNPs (∼9 nm) display a high-pressure simple hexagonal phase dominated plasticity. Meanwhile, dislocation activity exists in all of the phases, but significantly weakens as the particle size decreases and only leads to subtle plasticity in the initial diamond cubic phase. Furthermore, texture simulations identify major active slip systems in all of the phases. These findings elucidate the origin of plasticity in nanostructured Si under stress and provide key guidance for the application of nanostructured Si.",

author = "Zhidan Zeng and Qiaoshi Zeng and Mingyuan Ge and Bin Chen and Hongbo Lou and Xiehang Chen and Jinyuan Yan and Wenge Yang and Mao, \{Ho Kwang\} and Deren Yang and Mao, \{Wendy L.\}",

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doi = "10.1103/PhysRevLett.124.185701",

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AU - Zeng, Zhidan

AU - Zeng, Qiaoshi

AU - Ge, Mingyuan

AU - Chen, Bin

AU - Lou, Hongbo

AU - Chen, Xiehang

AU - Yan, Jinyuan

AU - Yang, Wenge

AU - Mao, Ho Kwang

AU - Yang, Deren

AU - Mao, Wendy L.

PY - 2020/5/8

Y1 - 2020/5/8

N2 - The mechanism of plasticity in nanostructured Si has been intensively studied over the past decade but still remains elusive. Here, we used in situ high-pressure radial x-ray diffraction to simultaneously monitor the deformation and structural evolution of a large number of randomly oriented Si nanoparticles (SiNPs). In contrast to the high-pressure β-Sn phase dominated plasticity observed in large SiNPs (∼100 nm), small SiNPs (∼9 nm) display a high-pressure simple hexagonal phase dominated plasticity. Meanwhile, dislocation activity exists in all of the phases, but significantly weakens as the particle size decreases and only leads to subtle plasticity in the initial diamond cubic phase. Furthermore, texture simulations identify major active slip systems in all of the phases. These findings elucidate the origin of plasticity in nanostructured Si under stress and provide key guidance for the application of nanostructured Si.

AB - The mechanism of plasticity in nanostructured Si has been intensively studied over the past decade but still remains elusive. Here, we used in situ high-pressure radial x-ray diffraction to simultaneously monitor the deformation and structural evolution of a large number of randomly oriented Si nanoparticles (SiNPs). In contrast to the high-pressure β-Sn phase dominated plasticity observed in large SiNPs (∼100 nm), small SiNPs (∼9 nm) display a high-pressure simple hexagonal phase dominated plasticity. Meanwhile, dislocation activity exists in all of the phases, but significantly weakens as the particle size decreases and only leads to subtle plasticity in the initial diamond cubic phase. Furthermore, texture simulations identify major active slip systems in all of the phases. These findings elucidate the origin of plasticity in nanostructured Si under stress and provide key guidance for the application of nanostructured Si.

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DO - 10.1103/PhysRevLett.124.185701

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JO - Physical Review Letters

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Origin of Plasticity in Nanostructured Silicon

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