Carbon concentration of standing and downed woody detritus: Effects of tree taxa, decay class, position, and tissue type

Carbon concentration of standing and downed woody detritus: Effects of tree taxa, decay class, position, and tissue type

► Angiosperms had a significantly lower carbon concentration than gymnosperms. ► Carbon concentration of gymnosperms increased by ∼10% as decomposition proceeded. ► Angiosperms showed no change in carbon concentration as decomposition proceeded. ► Standing dead wood had higher carbon concentration t...

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Bibliographic Details
Published in:Forest ecology and management Vol. 291; pp. 259 - 267
Main Authors: Harmon, Mark E., Fasth, Becky, Woodall, Christopher W., Sexton, Jay
Format: Journal Article
Language:English
Published: Kidlington Elsevier B.V 01-03-2013
Elsevier
Subjects:
Angiosperm
Angiosperms
Animal and plant ecology
Animal, plant and microbial ecology
Bark
Biological and medical sciences
Carbon
Coarse woody debris
Decay
Decomposition
Forestry
Forests
Fundamental and applied biological sciences. Psychology
Gymnosperm
Synecology
Terrestrial ecosystems
Trees
Wood
Gymnosperm
Angiosperm
Wood
Coarse woody debris
Carbon
Bark
Organic matter
Position
Forest ecology
Decomposition
Concentration
Type
Dead wood
Angiospermae
Forestry
Gymnospermae
Spermatophyta
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Summary:► Angiosperms had a significantly lower carbon concentration than gymnosperms. ► Carbon concentration of gymnosperms increased by ∼10% as decomposition proceeded. ► Angiosperms showed no change in carbon concentration as decomposition proceeded. ► Standing dead wood had higher carbon concentration than downed dead wood. ► Errors of up to 14% could be introduced by assuming a 50% concentration. The degree to which carbon concentration (CC) of woody detritus varies by tree taxa, stage of decay, tissue type (i.e., bark versus wood), and vertical orientation was examined in samples of 60 tree species from the Northern Hemisphere. The mean CC of 257 study samples was 49.3% with a range of 43.4–56.8%. Angiosperms had a significantly lower CC than gymnosperms, with means of 47.8% and 50.6%, respectively. For whole-stems (i.e., wood and bark), the CC of gymnosperms significantly increased from 49.3% to 53.5% with decomposition, while angiosperms had no significant change. The CC of bark was higher than wood across all stages of decay by an average of ∼1.0%. A similar magnitude of difference was found for standing versus downed dead wood in the later stages of decay, with the former having a higher CC than the latter. Differences between angiosperms and gymnosperms are hypothesized to be associated with initial lignin concentrations as well as subsequent decomposition by white- versus brown-rot fungal functional groups. The higher abundance of brown-rots in decomposing gymnosperms may lead to an increase in lignin concentrations, a compound that has higher CC than cellulose. As a result of these findings, uncertainties associated with forest carbon inventories may be reduced by using detrital CC specific to general taxa (angiosperms versus gymnosperms) and stage of decay rather than a single assumed value of 50% as commonly practiced.
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content type line 23
ISSN:0378-1127
1872-7042
DOI:10.1016/j.foreco.2012.11.046