Your search keyword '"Stephen D. Davis"' showing total 2 results

1. Dense but flexible wood – How leaf nodes impact xylem mechanics in Juglans californica

Author

Frank W. Ewers, Edward G. Bobich, Brett A. Bergman, Yasuhiro Utsumi, and Stephen D. Davis

Subjects

0106 biological sciences, Flexibility (anatomy), Stiffness, Xylem, Forestry, Flexural rigidity, Young's modulus, Plant Science, Bending, 010603 evolutionary biology, 01 natural sciences, symbols.namesake, Tree (data structure), medicine.anatomical_structure, Node (computer science), medicine, symbols, medicine.symptom, Composite material, 010606 plant biology & botany

Abstract

A node is the point of attachment of the leaf to the stem of a plant; gaps associated with nodes have been viewed as discontinuities of the stem vascular system. We tested the hypothesis that the node/gap is a spring-like joint that impacts stem flexibility even well after the leaves have been shed, with some stems specialized for elongation and others for flexibility. Four-point bending tests were done using an Instron Mechanical Testing Device with the independent variable being the number of nodes in the stem segment and dependent variables being Modulus of Elasticity (MOE), Modulus of Rupture (MOR), and xylem density. Node anatomy was examined microscopically to assess structure and function. The stiffness of the stem was inversely proportional to the frequency of leaf nodes. Surprisingly, xylem density was inversely proportional to the frequency of leaf nodes in stems of adult trees. The tissue around nodes/gaps consisted of twisted and contorted cells that may be effective at absorbing compressive and tensile stresses. Because nodes behave as spring-like joints, the frequency of nodes relates to function, with some stems specialized for vertical expansion and others for light capture and damping of wind stress. The ultimate stems on a tree are the most bendable, which may allow the trees to avoid breakage.

Published

2018

2. Biophysical Perspectives of Xylem Evolution: is there a Tradeoff of Hydraulic Efficiency for Vulnerability to Dysfunction?

Author

Hervé Cochard, Melvin T. Tyree, and Stephen D. Davis

Subjects

Hydraulic efficiency, Water transport, Ecology, Cavitation, food and beverages, Xylem, Forestry, Plant Science, Mechanics, Structure and function

Abstract

In this review, we discuss the evolution of xylem structure in the context of our current understanding of the biophysics of water transport in plants. Water transport in land plants occurs while water is under negative pressure and is thus in a metastable state. Vessels filled with metastable water are prone to dysfunction by cavitation whenever gas-filled voids appear in the vessel lumen. Cavitated vessels fill with air and are incapable of water transport until air bubbles dissolve. We know much more about how cavitations occur and the conditions under which air bubbles (embolisms) dissolve. This gives us an improved understanding of the relations hip between xylem structure and function.

Published

1994