Allometric Relationships for Predicting Aboveground Biomass and Sapwood Area of Oneseed Juniper (Juniperus monosperma) Trees.

Andrew M Cunliffe,Katherine J Sauer,Cameron D Mcintire,Richard E Brazier,Marcy Litvak,Karen Anderson,Fabio Boschetti

doi:10.3389/fpls.2020.00094

Andrew M Cunliffe, Katherine J Sauer + Show 5 more

Open Access

https://doi.org/10.3389/fpls.2020.00094

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Abstract

Across the semiarid ecosystems of the southwestern USA, there has been widespread encroachment of woody shrubs and trees including Juniperus species into former grasslands. Quantifying vegetation biomass in such ecosystems is important because semiarid ecosystems are thought to play an important role in the global land carbon (C) sink, and changes in plant biomass also have implications for primary consumers and potential bioenergy feedstock. Oneseed juniper (Juniperus monosperma) is common in desert grasslands and pinyon–juniper rangelands across the intermountain region of southwestern North America; however, there is limited information about the aboveground biomass (AGB) and sapwood area (SWA) for this species, causing uncertainties in estimates of C stock and transpiration fluxes. In this study, we report on canopy area (CA), stem diameter, maximum height, and biomass measurements from J. monosperma trees sampled from central New Mexico. Dry biomass ranged between 0.4 kg and 625 kg, and cross-sectional SWA was measured on n = 200 stems using image analysis. We found a strong linear relationship between CA and AGB (r2 = 0.96), with a similar slope to that observed in other juniper species, suggesting that this readily measured attribute is well suited for upscaling studies. There was a 9% bias between different approaches to measuring CA, indicating care should be taken to account for these differences to avoid systematic biases. We found equivalent stem diameter (ESD) was a strong predictor of biomass, but that existing allometric models underpredicted biomass in larger trees. We found SWA could be predicted from individual stem diameter with a power relationship, and that tree-level SWA should be estimated by summing the SWA predictions from individual stems rather than ESD. Our improved allometric models for J. monosperma support more accurate and robust measurements of C storage and transpiration fluxes in Juniperus-dominated ecosystems.

Highlights

There is increasing scientific and societal interest in the spatial and temporal dynamics of dryland vegetation
Better estimates of ecosystem functions including C storage and transpiration are important for understanding the role of semiarid ecosystems at local, regional, and global scales
Measuring 18 trees with dry masses ranging from 0.4 to 625 kg, we found that equivalent stem diameter (ESD) was a strong predictor of aboveground biomass (AGB); the relationship increased much more steeply than predicted by existing models, suggesting that existing allometric functions are poorly suited to J. monosperma

Summary

Introduction

There is increasing scientific and societal interest in the spatial and temporal dynamics of dryland vegetation. Juniperus monosperma is among the most drought-tolerant tree species in the southwestern USA, as it has demonstrated the ability to transpire and assimilate C at soil water potential thresholds well below those which are considered typically fatal for other cooccurring species (McDowell et al, 2008a; Gentine et al, 2015; Mackay et al, 2015) The range of this species is expected to expand under a predicted drier climate (Van Auken and Smeins, 2008), juniper mortality may increase in the future (Breshears et al, 2005; Gitlin et al, 2006; Kane et al, 2011)

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