Coarse Woody Debris Decomposition Assessment Tool: Model Validation and Application

Authors

Zhaohua Dai, USDA Forest ServiceFollow
Carl C. Trettin, USDA Forest Service
Andrew J. Burton, Michigan Technological University
Martin F. Jurgensen, Michigan Technological University
Deborah S. Page-Dumroese, USDA Forest Service
Brian T. Forschler, University of Georgia
Jonathan S. Schilling, University of Minnesota
Daniel L. Lindner, USDA Forest Service

Document Type

Article

Journal/Book Title/Conference

PLoS ONE

Volume

16

Issue

7

Publisher

Public Library of Science

First Page

1

Last Page

18

Publication Date

7-9-2021

Creative Commons License

This work has been identified with a Creative Commons Public Domain Mark 1.0.

Abstract

Coarse woody debris (CWD) is a significant component of the forest biomass pool; hence a model is warranted to predict CWD decomposition and its role in forest carbon (C) and nutrient cycling under varying management and climatic conditions. A process-based model, CWDDAT (Coarse Woody Debris Decomposition Assessment Tool) was calibrated and validated using data from the FACE (Free Air Carbon Dioxide Enrichment) Wood Decomposition Experiment utilizing pine (Pinus taeda), aspen (Populous tremuloides) and birch (Betula papyrifera) on nine Experimental Forests (EF) covering a range of climate, hydrology, and soil conditions across the continental USA. The model predictions were evaluated against measured FACE log mass loss over 6 years. Four widely applied metrics of model performance demonstrated that the CWDDAT model can accurately predict CWD decomposition. The R² (squared Pearson’s correlation coefficient) between the simulation and measurement was 0.80 for the model calibration and 0.82 for the model validation (P<0.01). The predicted mean mass loss from all logs was 5.4% lower than the measured mass loss and 1.4% lower than the calculated loss. The model was also used to assess the decomposition of mixed pine-hardwood CWD produced by Hurricane Hugo in 1989 on the Santee Experimental Forest in South Carolina, USA. The simulation reflected rapid CWD decomposition of the forest in this subtropical setting. The predicted dissolved organic carbon (DOC) derived from the CWD decomposition and incorporated into the mineral soil averaged 1.01 g C m^-2 y^-1 over the 30 years. The main agents for CWD mass loss were fungi (72.0%) and termites (24.5%), the remainder was attributed to a mix of other wood decomposers. These findings demonstrate the applicability of CWDDAT for large-scale assessments of CWD dynamics, and fine-scale considerations regarding the fate of CWD carbon.

Recommended Citation

Dai Z, Trettin CC, Burton AJ, Jurgensen MF, Page-Dumroese DS, Forschler BT, et al. (2021) Coarse Woody Debris Decomposition Assessment Tool: Model validation and application. PLoS ONE 16(7): e0254408. https://doi.org/10.1371/journal.pone.0254408