Capturing spiral radial growth of conifers using the superellipse to model tree-ring geometric shape.

Jacques C Tardif,Bai-Lian Li,Pei-Jian Shi,Cang Hui,Jian-Guo Huang,Henri D Grissino-Mayer,Li-Hong Zhai,Fu-Sheng Wang

doi:10.3389/fpls.2015.00856

Abstract

Tree-rings are often assumed to approximate a circular shape when estimating forest productivity and carbon dynamics. However, tree rings are rarely, if ever, circular, thereby possibly resulting in under- or over-estimation in forest productivity and carbon sequestration. Given the crucial role played by tree ring data in assessing forest productivity and carbon storage within a context of global change, it is particularly important that mathematical models adequately render cross-sectional area increment derived from tree rings. We modeled the geometric shape of tree rings using the superellipse equation and checked its validation based on the theoretical simulation and six actual cross sections collected from three conifers. We found that the superellipse better describes the geometric shape of tree rings than the circle commonly used. We showed that a spiral growth trend exists on the radial section over time, which might be closely related to spiral grain along the longitudinal axis. The superellipse generally had higher accuracy than the circle in predicting the basal area increment, resulting in an improved estimate for the basal area. The superellipse may allow better assessing forest productivity and carbon storage in terrestrial forest ecosystems.

Highlights

Tree rings are natural archives of environmental changes and they have long been used in exploring the effects of endogenous and exogenous factors on tree growth (Fritts, 1976)
Mean annual ring-width is often calculated from two radial growth measurements along two directions with an angle of between 90◦ and 180◦ on a cross section collected at diameter at breast height (DBH)
The relevant R functions to calculate the area encircled by a tree ring and the confidence interval (CI) of the model parameters are provided in Appendices S1 and S2

Summary

INTRODUCTION

Tree rings are natural archives of environmental changes and they have long been used in exploring the effects of endogenous (e.g., competition) and exogenous (e.g., climate, disturbances) factors on tree growth (Fritts, 1976). Forest sciences including tree-ring techniques often have assumed that tree rings on a cross section approximate a series of concentric circles (Biondi and Qeadan, 2008; West, 2009) Based on this assumption, mean annual ring-width and basal area increment are usually obtained and commonly used as two basic parameters for investigating environmental effects on growth and for assessing forest growth, productivity, and carbon sequestration. We attempt to: (1) use the superellipse equation to model tree-ring shapes of conifers which usually bear clear annual ring growth pattern; and (2) explore whether any spiral growth exists along the radial section over time and, if it does, determine whether it is related to spiral grain over the longitudinal axis

MATERIALS AND METHODS

Evaluation

RESULTS

DISCUSSION