Mechanical investigations of the peltate leaf of Stephania japonica (Menispermaceae): Experiments and a continuum mechanical material model

Mechanical investigations of the peltate leaf of Stephania japonica (Menispermaceae): Experiments and a continuum mechanical material model

is a slender climbing plant with peltate, triangular-ovate leaves. Not many research efforts have been devoted to investigate the anatomy and the mechanical properties of this type of leaf shape. In this study, displacement driven tensile tests with three cycles on different displacement levels are...

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Published in:Frontiers in plant science Vol. 13; p. 994320
Main Authors: Macek, Domen, Holthusen, Hagen, Rjosk, Annabell, Ritzert, Stephan, Lautenschläger, Thea, Neinhuis, Christoph, Simon, Jaan-Willem, Reese, Stefanie
Format: Journal Article
Language:English
Published: Switzerland Frontiers Media S.A 27-01-2023
Subjects:
anisotropy
finite strains
material model
mechanical investigations
Plant Science
Stephania japonica
viscoelasticity
finite strains
mechanical investigations
Stephania japonica
material model
anisotropy
viscoelasticity
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Summary:is a slender climbing plant with peltate, triangular-ovate leaves. Not many research efforts have been devoted to investigate the anatomy and the mechanical properties of this type of leaf shape. In this study, displacement driven tensile tests with three cycles on different displacement levels are performed on petioles, venation and intercostal areas of the leaves. Furthermore, compression tests in longitudinal direction are performed on petioles. The mechanical experiments are combined with light microscopy and X-ray tomography. The experiments show, that these plant organs and tissues behave in the finite strain range in a viscoelastic manner. Based on the results of the light microscopy and X-ray tomography, the plant tissue can be considered as a matrix material reinforced by fibers. Therefore, a continuum mechanical anisotropic viscoelastic material model at finite deformations is proposed to model such behavior. The anisotropy is specified as the so-called transverse isotropy, where the behavior in the plane perpendicular to the fibers is assumed to be isotropic. The model is obtained by postulating a Helmholtz free energy, which is split additively into an elastic and an inelastic part. Both parts of the energy depend on structural tensors to account for the transversely isotropic material behavior. The evolution equations for the internal variables, e.g. inelastic deformations, are chosen in a physically meaningful way that always fulfills the second law of thermodynamics. The proposed model is calibrated against experimental data, and the material parameters are identified. The model can be used for finite element simulations of this type of leaf shape, which is left open for the future work.
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This article was submitted to Plant Biophysics and Modeling, a section of the journal Frontiers in Plant Science
Reviewed by: Patrick Werner Dondl, University of Freiburg, Germany; David Taylor, Trinity College Dublin, Ireland
Edited by: Olga Speck, University of Freiburg, Germany
ISSN:1664-462X
1664-462X
DOI:10.3389/fpls.2022.994320