期刊
FOREST ECOLOGY AND MANAGEMENT
卷 291, 期 -, 页码 336-343出版社
ELSEVIER
DOI: 10.1016/j.foreco.2012.11.043
关键词
Aboveground carbon storage; Climate change; Hawaii; Metrosideros polymorpha; Tree fern
类别
资金
- National Science Foundation [DEB-0816486]
- USDA Forest Service, Pacific Southwest Research Station, Institute of Pacific Islands Forestry [09-JV-11272177-029]
- College of Tropical Agriculture and Human Resources, University of Hawaii at Mama via the USDA National Institute of Food and Agriculture, Hatch and McIntire-Stennis Programs [HAW00132-H, HAW00188-M]
Coarse woody debris (CWD; defined here as fallen and standing dead trees and tree ferns) is a critical structural and functional component of forest ecosystems that typically comprises a large proportion of total aboveground carbon (C) storage. However, CWD estimates for the tropics are uncommon, and little is known about how C storage in CWD will respond to climate change. Given the predominant role that tropical forests play in global C cycling, this information gap compromises efforts to forecast climate change impacts on terrestrial C balance. The primary objectives of this study were to: (i) quantify CWD C storage in a tropical montane wet forest; and (ii) determine if CWD C storage varies with mean annual temperature (MAT). Coarse woody debris C was quantified with line-intercept sampling techniques in nine permanent plots located across a highly constrained 5.2 degrees C MAT gradient spanning 800 m elevation on the eastern slope of Mauna Kea Volcano, Island of Hawaii. Forests across this tropical montane MAT gradient contained large quantities of CWD C (44.3 +/- 11.2 Mg ha(-1); Mean +/- 1 SE), which accounted for an estimated 17% of total aboveground C storage. Across the entire gradient, CWD C was found primarily as: moderately decayed CWD (Decay Class 2); tree CWD; fallen CWD; and small diameter CWD (2-10 cm). Tree ferns accounted for an average of similar to 20% of total CWD C, but are rarely included in tropical CWD estimates. Overall, total CWD C ranged from 12.2 to 104.6 Mg ha(-1) across the MAT gradient, and decreased with increasing MAT. The negative relationship between CWD and MAT was driven by large accumulations of standing tree CWD at cooler MATs, as fallen CWD did not vary with MAT. The results presented here are in line with limited evidence from tropical studies showing that CWD can make up a large fraction of total aboveground C storage. In addition, these data suggest that CWD could become a net C source to the atmosphere in tropical forests with future warming. A decrease in tropical montane CWD C storage would have important implications for global C dynamics and atmospheric CO2 levels. (C) 2012 Elsevier B.V. All rights reserved.
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