Biomechanical design and long-term stability of trees: Morphological and wood traits involved in the balance between weight increase and the gravitropic reaction

Alméras, Tancrède; Fournier, Mériem

doi:10.1016/j.jtbi.2008.10.011

Cited by 86 publications

(92 citation statements)

References 33 publications

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“…It compensates for the comparatively low compressive strength of wood and thus improves the stem resistance against bending loads. It also provides the tree with a motor system (Moulia et al, 2006), necessary to maintain the stem at a constant angle during growth (Alméras and Fournier, 2009) or to achieve adaptive reorientations. In angiosperms, a large tensile maturation stress is generated by a specialized tissue called "tension wood."…”

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confidence: 99%

Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

et al. 2010

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Tension wood is widespread in the organs of woody plants. During its formation, it generates a large tensile mechanical stress, called maturation stress. Maturation stress performs essential biomechanical functions such as optimizing the mechanical resistance of the stem, performing adaptive movements, and ensuring long-term stability of growing plants. Although various hypotheses have recently been proposed, the mechanism generating maturation stress is not yet fully understood. In order to discriminate between these hypotheses, we investigated structural changes in cellulose microfibrils along sequences of xylem cell differentiation in tension and normal wood of poplar (Populus deltoides 3 Populus trichocarpa 'I45-51'). Synchrotron radiation microdiffraction was used to measure the evolution of the angle and lattice spacing of crystalline cellulose associated with the deposition of successive cell wall layers. Profiles of normal and tension wood were very similar in early development stages corresponding to the formation of the S1 and the outer part of the S2 layer. The microfibril angle in the S2 layer was found to be lower in its inner part than in its outer part, especially in tension wood. In tension wood only, this decrease occurred together with an increase in cellulose lattice spacing, and this happened before the G-layer was visible. The relative increase in lattice spacing was found close to the usual value of maturation strains, strongly suggesting that microfibrils of this layer are put into tension and contribute to the generation of maturation stress.

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confidence: 99%

Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

et al. 2010

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“…Pre-tension in the stem periphery is beneficial for its strength, since wood is weaker in compression than in tension [6]. The asymmetric distribution of this stress around the stem circumference [7], with higher magnitude on one side of the stem, generates a bending moment, which enables reorientations or compensates for increasing self-weight [5].…”

Section: Wood Maturation Provides the Motor Powermentioning

confidence: 99%

Critical review on the mechanisms of maturation stress generation in trees

Alméras

Clair

2016

J. R. Soc. Interface.

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Trees control their posture by generating asymmetric mechanical stress around the periphery of the trunk or branches. This stress is produced in wood during the maturation of the cell wall. When the need for reaction is high, it is accompanied by strong changes in cell organization and composition called reaction wood, namely compression wood in gymnosperms and tension wood in angiosperms. The process by which stress is generated in the cell wall during its formation is not yet known, and various hypothetical mechanisms have been proposed in the literature. Here we aim at discriminating between these models. First, we summarize current knowledge about reaction wood structure, state and behaviour relevant to the understanding of maturation stress generation. Then, the mechanisms proposed in the literature are listed and discussed in order to identify which can be rejected based on their inconsistency with current knowledge at the frontier between plant science and mechanical engineering.

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“…Each of these levels shows a characteristic architecture, that is, dependent both on the tree species and the location within the tree. In addition to this, environmental conditions are also reflected in the material architecture at particular length scales, like the formation of reaction wood which generates active stresses that allow the tree to direct organs in particular directions (Wardrop 1965;Scurfield 1973;Archer 1986;Bonser and Ennos 1998;Yamamoto et al 2002;Moulia et al 2006;Burgert et al 2007;Alméras and Fournier 2009). All these dependencies of properties on wood structure are equally important from both a biological and a technological perspective.…”

Section: Wood Architecture and Propertiesmentioning

confidence: 99%

Experimental micromechanical characterisation of wood cell walls

et al. 2012

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The properties of wood and wood-based materials are strongly dependent on the properties of the fibres, that is, the cell wall properties. It is thus highly important to be able to mechanically characterise cell walls in order to understand structure-property relationships. This article gives a brief overview of the state of the art in experimental techniques to characterise the mechanical properties of wood at both the level of the single cell and that of the cell wall. Challenges, opportunities, drawbacks and limitations of single fibre tensile tests and nanoindentation are discussed with respect to the wood material properties. Introduction and background

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Biomechanical design and long-term stability of trees: Morphological and wood traits involved in the balance between weight increase and the gravitropic reaction

Cited by 86 publications

References 33 publications

Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

Maturation Stress Generation in Poplar Tension Wood Studied by Synchrotron Radiation Microdiffraction

Critical review on the mechanisms of maturation stress generation in trees

Experimental micromechanical characterisation of wood cell walls

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