Fracture behavior of SiGe nanosheets: Mechanics of monocrystalline vs. polycrystalline structure

Maryam Zarghami Dehaghani; Mohammad Esmaeili Safa; Farrokh Yousefi; Azam Salmankhani; Zohre Karami; Ali Dadrasi; Amin Hamed Mashhadzadeh; Florian J. Stadler; Mohammad Reza Saeb

doi:10.1016/j.engfracmech.2021.107782

Fracture behavior of SiGe nanosheets: Mechanics of monocrystalline vs. polycrystalline structure

Maryam Zarghami Dehaghani
, Mohammad Esmaeili Safa
, Farrokh Yousefi
, Azam Salmankhani
, Zohre Karami
, Ali Dadrasi
, Amin Hamed Mashhadzadeh^*
, Florian J. Stadler
, Mohammad Reza Saeb

^*Corresponding author for this work

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

20 Scopus citations

Abstract

2D materials present promising features, but their intrinsic defects, especially at high temperatures, should be considered for usage under harsh conditions. Molecular dynamics simulations were utilized in this work to explore the mechanics of monocrystalline and polycrystalline (PC) silicon–germanium nanosheets (MSiGeNS and PSiGeNS, respectively) as a function of temperature. The mechanical properties of MSiGeNSs decreased by increase of temperature in both armchair and zigzag directions. Likewise, Young's modulus, E and failure stress, σ_f of decreased by increasing grain-size and randomness, while failure strain, ∊_f remained almost unaffected. Ultimately, the study of the mechanical properties of MSiGeNS subjected to different sizes of cracks and notches as a function of temperature showed that increasing crack length, notch radius, and temperature reduced all the properties of defective MSiGeNS. Samples possessing circular notches showed poorer properties compared to those with a crack defect. Moreover, the stress intensity factor of cracked MSiGeNS dropped sharply by temperature rise.

Original language	English
Article number	107782
Journal	Engineering Fracture Mechanics
Volume	251
DOIs	https://doi.org/10.1016/j.engfracmech.2021.107782
State	Published - 15 Jun 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 Elsevier Ltd

Keywords

Fracture Mechanics
Mechanical properties
Molecular dynamic simulation
Polycrystalline
Silicon-germanium nano-sheets

ASJC Scopus subject areas

General Materials Science
Mechanics of Materials
Mechanical Engineering

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10.1016/j.engfracmech.2021.107782

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title = "Fracture behavior of SiGe nanosheets: Mechanics of monocrystalline vs. polycrystalline structure",

abstract = "2D materials present promising features, but their intrinsic defects, especially at high temperatures, should be considered for usage under harsh conditions. Molecular dynamics simulations were utilized in this work to explore the mechanics of monocrystalline and polycrystalline (PC) silicon–germanium nanosheets (MSiGeNS and PSiGeNS, respectively) as a function of temperature. The mechanical properties of MSiGeNSs decreased by increase of temperature in both armchair and zigzag directions. Likewise, Young's modulus, E and failure stress, σf of decreased by increasing grain-size and randomness, while failure strain, ∊f remained almost unaffected. Ultimately, the study of the mechanical properties of MSiGeNS subjected to different sizes of cracks and notches as a function of temperature showed that increasing crack length, notch radius, and temperature reduced all the properties of defective MSiGeNS. Samples possessing circular notches showed poorer properties compared to those with a crack defect. Moreover, the stress intensity factor of cracked MSiGeNS dropped sharply by temperature rise.",

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author = "\{Zarghami Dehaghani\}, Maryam and \{Esmaeili Safa\}, Mohammad and Farrokh Yousefi and Azam Salmankhani and Zohre Karami and Ali Dadrasi and \{Hamed Mashhadzadeh\}, Amin and Stadler, \{Florian J.\} and Saeb, \{Mohammad Reza\}",

note = "Publisher Copyright: {\textcopyright} 2021 Elsevier Ltd",

year = "2021",

month = jun,

day = "15",

doi = "10.1016/j.engfracmech.2021.107782",

language = "English",

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T2 - Mechanics of monocrystalline vs. polycrystalline structure

AU - Zarghami Dehaghani, Maryam

AU - Esmaeili Safa, Mohammad

AU - Yousefi, Farrokh

AU - Salmankhani, Azam

AU - Karami, Zohre

AU - Dadrasi, Ali

AU - Hamed Mashhadzadeh, Amin

AU - Stadler, Florian J.

AU - Saeb, Mohammad Reza

PY - 2021/6/15

Y1 - 2021/6/15

N2 - 2D materials present promising features, but their intrinsic defects, especially at high temperatures, should be considered for usage under harsh conditions. Molecular dynamics simulations were utilized in this work to explore the mechanics of monocrystalline and polycrystalline (PC) silicon–germanium nanosheets (MSiGeNS and PSiGeNS, respectively) as a function of temperature. The mechanical properties of MSiGeNSs decreased by increase of temperature in both armchair and zigzag directions. Likewise, Young's modulus, E and failure stress, σf of decreased by increasing grain-size and randomness, while failure strain, ∊f remained almost unaffected. Ultimately, the study of the mechanical properties of MSiGeNS subjected to different sizes of cracks and notches as a function of temperature showed that increasing crack length, notch radius, and temperature reduced all the properties of defective MSiGeNS. Samples possessing circular notches showed poorer properties compared to those with a crack defect. Moreover, the stress intensity factor of cracked MSiGeNS dropped sharply by temperature rise.

AB - 2D materials present promising features, but their intrinsic defects, especially at high temperatures, should be considered for usage under harsh conditions. Molecular dynamics simulations were utilized in this work to explore the mechanics of monocrystalline and polycrystalline (PC) silicon–germanium nanosheets (MSiGeNS and PSiGeNS, respectively) as a function of temperature. The mechanical properties of MSiGeNSs decreased by increase of temperature in both armchair and zigzag directions. Likewise, Young's modulus, E and failure stress, σf of decreased by increasing grain-size and randomness, while failure strain, ∊f remained almost unaffected. Ultimately, the study of the mechanical properties of MSiGeNS subjected to different sizes of cracks and notches as a function of temperature showed that increasing crack length, notch radius, and temperature reduced all the properties of defective MSiGeNS. Samples possessing circular notches showed poorer properties compared to those with a crack defect. Moreover, the stress intensity factor of cracked MSiGeNS dropped sharply by temperature rise.

KW - Fracture Mechanics

KW - Mechanical properties

KW - Molecular dynamic simulation

KW - Polycrystalline

KW - Silicon-germanium nano-sheets

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VL - 251

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ER -

Fracture behavior of SiGe nanosheets: Mechanics of monocrystalline vs. polycrystalline structure

Abstract

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Keywords

ASJC Scopus subject areas

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