Elastic properties of polycrystalline silicon: experimental findings, effective estimates, and their relations

Aßmus, Marcus; Altenbach, Holm

doi:10.1007/s00161-023-01201-3

Cited by 4 publications

(5 citation statements)

References 84 publications

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“…To be specific, a certain part of the experimental results lie outside the theoretically admissible range, for isotropic and anisotropic aggregates. This problem is revealed and discussed by Aßmus and Altenbach [5]. In the present treatise, we want to address this phenomenon by means of computational investigations.…”

Section: Introductionmentioning

confidence: 85%

“…

\begin{align} \lambda ^{\mathrm{c}}_{1}=C_{1111}+2C_{1122}&&\lambda ^{\mathrm{c}}_{2}=C_{1111}-C_{1122}&&\lambda ^{\mathrm{c}}_{3}=2C_{2323} \end{align}

For silicon crystal aggregates, that is, silicon polycrystals, isotropy (superscript ○) is often assumed, at least in experiments, cf. [5]. In the isotropic case, the projector representation reduces to:

\begin{align} \mbox{\boldmath $\mathbb {C}$}^{\circ }=\lambda ^{\circ }_{1} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1}+\lambda ^{\circ }_{2} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{2} && \begin{aligned} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1}&=\mbox{\boldmath $\mathbb {P}$}^{\mathrm{c}}_{1}=\frac{1}{3}\mbox{\boldmath $I$}\otimes \mbox{\boldmath $I$}\\ \mbox{\boldmath $\mathbb {P}$}^{\circ }_{2}&=\mbox{\boldmath $\mathbb {I}$}^{\mathrm{sym}}- \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1} \end{aligned} \end{align}

The isotropic eigenvalues are related to the engineering parameters as follows.…”

Section: Constitutive Relationsmentioning

confidence: 99%

“…For silicon crystal aggregates, that is, silicon polycrystals, isotropy (superscript •) is often assumed, at least in experiments, cf. [5]. In the isotropic case, the projector representation reduces to:…”

Section: 𝑻 = ℂ∶ 𝑬mentioning

confidence: 99%

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Size effects in numerical homogenization of polycrystalline silicon

Weber,

Aßmus,

Glüge

et al. 2023

Proc Appl Math and Mech

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A current topic in the photovoltaic industry is the analysis and evaluation of possible structural and material properties. This requires the effective material characteristics of polycrystalline silicon, which is an important component for the functional performance of the photovoltaic modules in use. Since this assessment is associated with high costs, it is to be carried out already in the product development process. Due to very thin silicon layers, the effect of the layer thickness on the effective material characteristics has to be investigated (see ). In this work, a procedure to determine these characteristic values is listed to investigate the size effect on different film thicknesses of this material (see ). With the knowledge of the properties of the silicon single crystal with its cubic symmetry on the micro level, a homogenization of the properties to the macro level can be done. The polycrystal structure with a cubic sample geometry forms the macro level. This structure is now cut into thinning layers for investigation. The open‐source software Neper is used to create the crystal structure and the inter‐connectivity for this purpose. With the help of Matlab, this information is passed on to the finite element program Abaqus, where the results are evaluated after an elastic calculation using Python. The focus is on the expected change in material properties as a function of the layer thickness.

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Section: Introductionmentioning

confidence: 85%

“…

\begin{align} \lambda ^{\mathrm{c}}_{1}=C_{1111}+2C_{1122}&&\lambda ^{\mathrm{c}}_{2}=C_{1111}-C_{1122}&&\lambda ^{\mathrm{c}}_{3}=2C_{2323} \end{align}

\begin{align} \mbox{\boldmath $\mathbb {C}$}^{\circ }=\lambda ^{\circ }_{1} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1}+\lambda ^{\circ }_{2} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{2} && \begin{aligned} \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1}&=\mbox{\boldmath $\mathbb {P}$}^{\mathrm{c}}_{1}=\frac{1}{3}\mbox{\boldmath $I$}\otimes \mbox{\boldmath $I$}\\ \mbox{\boldmath $\mathbb {P}$}^{\circ }_{2}&=\mbox{\boldmath $\mathbb {I}$}^{\mathrm{sym}}- \mbox{\boldmath $\mathbb {P}$}^{\circ }_{1} \end{aligned} \end{align}

The isotropic eigenvalues are related to the engineering parameters as follows.…”

Section: Constitutive Relationsmentioning

confidence: 99%

See 1 more Smart Citation

Size effects in numerical homogenization of polycrystalline silicon

Weber,

Aßmus,

Glüge

et al. 2023

Proc Appl Math and Mech

Self Cite

View full text Add to dashboard Cite

show abstract

“…To be specific, a certain part of the experimental results lie outside the theoretically admissible range, for isotropic and anisotropic aggregates. This problem is revealed and discussed by Aßmus and Altenbach [12]. In the present treatise, we want to address this phenomenon by means of computational investigations.…”

Section: Introductionmentioning

confidence: 85%

“…For silicon crystal aggregates, that is, silicon polycrystals, isotropy (superscript

\circ

) is often assumed, at least in experiments, cf. [12]. In the isotropic case, the projector representation () reduces to

\chi =2

[16].…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Size effects in the elastic properties of polycrystalline silicon

et al. 2023

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Polycrystalline silicon has a wide range of applications in the semiconductor industry. Instead of components whose dimensions are of the same order of magnitude in all three spatial directions, thin slices are primarily used there. Deviating mechanical properties have been noticed among such thin configurations. In this work, we systematically investigate the size‐dependent effective elastic properties of polycrystalline silicon. This is realized by gradually reducing the thickness of such components, starting from a structure usually referred to as representative volume element. Based on the framework of continuum mechanics, we specify unit cell problems for aggregates whose microstructures are build artificially based on first‐order properties through tessellations. The effective responses of virtual material tests are determined by the aid of the finite element method. Based on a larger number of computational simulations with different but equivalent microstructures, the effective elastic properties of silicon polycrystals are evaluated statistically. The findings are examined with regard to geometrically‐induced symmetries by several methods. For the unconstrained configurations examined here, results show an increase in the scattering of the results where the average stiffness decreases with decreasing structural thickness. These outcomes are also compared to analytical estimates for silicon bulk configurations. This comparison indicates that the average stiffness varies in between a reasonable mean and the isotropic first‐order lower bound of the silicon bulk. Compared to experimental findings, admissible bounds of the stiffnesses are clearly outlined.

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New Structural Approach for Determination of Effective Thermoelastic Modules of Discrete Composite Layers

Marchuk,

Khomyak

2024

Advanced Structured Materials

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Elastic properties of polycrystalline silicon: experimental findings, effective estimates, and their relations

Cited by 4 publications

References 84 publications

Size effects in numerical homogenization of polycrystalline silicon

Size effects in numerical homogenization of polycrystalline silicon

Size effects in the elastic properties of polycrystalline silicon

New Structural Approach for Determination of Effective Thermoelastic Modules of Discrete Composite Layers

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