The Effects of Random Porosities in Resonant Frequencies of Graphene Based on the Monte Carlo Stochastic Finite Element Model

Chu, Liu; Shi, Jiajia; Yu, Yue; Cursi, Eduardo Souza de

doi:10.3390/ijms22094814

Cited by 6 publications

(8 citation statements)

References 53 publications

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“…The geometrical configuration of graphene lattice and the corresponding geometri and material parameters are defined as above, while the resonant frequencies and def mations under different vibration modes are computed based on the finite eleme method. The first four order resonant frequencies of the pristine graphene without v cancy defects are 1.7282, 3.2925, 3.7442, and 5.189 THz, respectively, which reaches go agreement with the reported literature [28,30,31].…”

Section: Flowchart Of Fingerprint Compilersupporting

confidence: 90%

“…The geometrical parameters involving the length of carbon covalent bonds and the diameter of the cross-section of the beam (thickness of graphene) are 0.27 nm and 0.032 nm, respectively. The material properties, namely Young's modulus, Poisson's ratio, and mass density, are settled as 1.2 TPa, 0.2, and 2700 Kg/m 3 , respectively, according to the reported literature [7,[28][29][30].…”

Section: Atomic Vacancy Defects In Graphenementioning

confidence: 99%

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The Fingerprints of Resonant Frequency for Atomic Vacancy Defect Identification in Graphene

2021

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The identification of atomic vacancy defects in graphene is an important and challenging issue, which involves inhomogeneous spatial randomness and requires high experimental conditions. In this paper, the fingerprints of resonant frequency for atomic vacancy defect identification are provided, based on the database of massive samples. Every possible atomic vacancy defect in the graphene lattice is considered and computed by the finite element model in sequence. Based on the sample database, the histograms of resonant frequency are provided to compare the probability density distributions and interval ranges. Furthermore, the implicit relationship between the locations of the atomic vacancy defects and the resonant frequencies of graphene is established. The fingerprint patterns are depicted by mapping the locations of atomic vacancy defects to the resonant frequency magnitudes. The geometrical characteristics of computed fingerprints are discussed to explore the feasibility of atomic vacancy defects identification. The work in this paper provides meaningful supplementary information for non-destructive defect detection and identification in nanomaterials.

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Section: Flowchart Of Fingerprint Compilersupporting

confidence: 90%

Section: Atomic Vacancy Defects In Graphenementioning

confidence: 99%

The Fingerprints of Resonant Frequency for Atomic Vacancy Defect Identification in Graphene

2021

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“…In addition to the related geometrical parameters in the finite plane element model of graphene, the material parameters are listed in Table 1 . According to the reported literature [ 10 , 11 ], the distinguished mechanical properties are measured and predicted. However, the uncertainty and obvious fluctuations of mechanical properties are the essential issues that require effective solutions.…”

Section: Methods Descriptionmentioning

confidence: 99%

“…However, the uncertainty and obvious fluctuations of mechanical properties are the essential issues that require effective solutions. In this paper, the specific value intervals of the geometrical and material parameters are provided according to the data in the literature [ 10 , 11 ] and presented in Table 1 .…”

Section: Methods Descriptionmentioning

confidence: 99%

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The Uncertainty Propagation for Carbon Atomic Interactions in Graphene under Resonant Vibration Based on Stochastic Finite Element Model

Shi

Chu

et al. 2022

Materials

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Graphene is one of the most promising two-dimensional nanomaterials with broad applications in many fields. However, the variations and fluctuations in the material and geometrical properties are challenging issues that require more concern. In order to quantify uncertainty and analyze the impacts of uncertainty, a stochastic finite element model (SFEM) is proposed to propagate uncertainty for carbon atomic interactions under resonant vibration. Compared with the conventional truss or beam finite element models, both carbon atoms and carbon covalent bonds are considered by introducing plane elements. In addition, the determined values of the material and geometrical parameters are expanded into the related interval ranges with uniform probability density distributions. Based on the SFEM, the uncertainty propagation is performed by the Monte Carlo stochastic sampling process, and the resonant frequencies of graphene are provided by finite element computation. Furthermore, the correlation coefficients of characteristic parameters are computed based on the database of SFEM. The vibration modes of graphene with the extreme geometrical values are also provided and analyzed. According to the computed results, the minimum and maximum values of the first resonant frequency are 0.2131 and 16.894 THz, respectively, and the variance is 2.5899 THz. The proposed SFEM is an effective method to propagate uncertainty and analyze the impacts of uncertainty in the carbon atomic interactions of graphene. The work in this paper provides an important supplement to the atomic interaction modeling in nanomaterials.

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A modified spring finite element model for graphene elastic properties study

Zhang

Huang

Jun

2023

Materials Today Communications

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The Effects of Random Porosities in Resonant Frequencies of Graphene Based on the Monte Carlo Stochastic Finite Element Model

Cited by 6 publications

References 53 publications

The Fingerprints of Resonant Frequency for Atomic Vacancy Defect Identification in Graphene

The Fingerprints of Resonant Frequency for Atomic Vacancy Defect Identification in Graphene

The Uncertainty Propagation for Carbon Atomic Interactions in Graphene under Resonant Vibration Based on Stochastic Finite Element Model

A modified spring finite element model for graphene elastic properties study

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