Boundary conditions for unit cells from periodic microstructures and their implications

The most important aspect of formulating unit cells for micromechanical analysis of materials of patterned microstructures is the derivation of appropriate boundary conditions for them. There is lack of a comprehensive account on the derivation of boundary conditions in the literature, while the use...

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Published in	Composites science and technology Vol. 68; no. 9; pp. 1962 - 1974
Main Author	Li, Shuguang
Format	Journal Article
Language	English
Published	Kidlington Elsevier Ltd 01.07.2008 Elsevier
Subjects	B. Mechanical properties C. Anisotropy C. Elastic properties C. Finite element analysis (FEA) C. Modelling Exact sciences and technology Fundamental areas of phenomenology (including applications) Physics Solid mechanics Static elasticity (thermoelasticity...) Structural and continuum mechanics Unit cells B. Mechanical properties C. Anisotropy C. Finite element analysis (FEA) C. Modelling Unit cells C. Elastic properties Fiber reinforced material Theoretical study Mechanical properties Dispersion reinforced material Boundary condition Modeling Composite material Periodic structure Micromechanics Finite element method Numerical simulation Elastic properties
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Abstract	The most important aspect of formulating unit cells for micromechanical analysis of materials of patterned microstructures is the derivation of appropriate boundary conditions for them. There is lack of a comprehensive account on the derivation of boundary conditions in the literature, while the use of unit cells in micromechanical analyses is on an increasing trend. This paper is devoted to the generation of such an account, where boundary conditions are derived entirely based on considerations of symmetries which are present in the microstructure. The implications of the boundary conditions used for a unit cell are not always clear and therefore have been discussed. It has been demonstrated that unit cells of the same appearance but subject to boundary conditions derived based on different symmetry considerations may behave rather differently. One of the objectives of the paper is to inform users of unit cells that to introduce a unit cell one needs not only mechanically correct boundary conditions but also a clear sense of the microstructure under consideration. Otherwise the results of such analyses could mislead.
AbstractList	The most important aspect of formulating unit cells for micromechanical analysis of materials of patterned microstructures is the derivation of appropriate boundary conditions for them. There is lack of a comprehensive account on the derivation of boundary conditions in the literature, while the use of unit cells in micromechanical analyses is on an increasing trend. This paper is devoted to the generation of such an account, where boundary conditions are derived entirely based on considerations of symmetries which are present in the microstructure. The implications of the boundary conditions used for a unit cell are not always clear and therefore have been discussed. It has been demonstrated that unit cells of the same appearance but subject to boundary conditions derived based on different symmetry considerations may behave rather differently. One of the objectives of the paper is to inform users of unit cells that to introduce a unit cell one needs not only mechanically correct boundary conditions but also a clear sense of the microstructure under consideration. Otherwise the results of such analyses could mislead.
Author	Li, Shuguang
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References	Li (bib1) 1999; 455 Adams, Crane (bib7) 1984; 18 Li (bib2) 2001; 32 Yeh (bib10) 1992; 29 Peng, Cao (bib5) 2002; 33 Llorca, Needleman, Suresh (bib6) 1991; 39 Li, Wongsto (bib3) 2004; 36 Lekhniskii (bib13) 1963 Zahl, Schmauder, McMeeking (bib9) 1994; 42 Nedele, Wisnom (bib8) 1994; 25 Fang, Yan, Sun, Shokoufandeh, Regli (bib4) 2005; 2 Fung, Tong (bib11) 2001 Aitharaju, Averill (bib12) 1999; 59
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SubjectTerms	B. Mechanical properties C. Anisotropy C. Elastic properties C. Finite element analysis (FEA) C. Modelling Exact sciences and technology Fundamental areas of phenomenology (including applications) Physics Solid mechanics Static elasticity (thermoelasticity...) Structural and continuum mechanics Unit cells
Title	Boundary conditions for unit cells from periodic microstructures and their implications
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