Modeling relationships between water table depth and peat soil carbon loss in Southeast Asian plantations

Plantation-associated drainage of Southeast Asian peatlands has accelerated in recent years. Draining exposes the upper peat layer to oxygen, leading to elevated decomposition rates and net soil carbon losses. Empirical studies indicate positive relationships between long-term water table (WT) depth...

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Bibliographic Details
Published in:Environmental research letters 2015-07, Vol.10 (7), p.74006
Main Authors: Carlson, Kimberly M, Goodman, Lael K, May-Tobin, Calen C
Format: Article
Language:English
Subjects:
acacia
Carbon
Carbon dioxide
Chambers
Climate change
Confidence intervals
Drainage
Fluxes
Global warming
Land use
oil palm
Organic fertilizers
Peat
Peat soils
Peatlands
Plantations
Respiration
soil respiration
Soils
Subsidence
tropics
Water depth
Water table
Water table depth
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Summary:Plantation-associated drainage of Southeast Asian peatlands has accelerated in recent years. Draining exposes the upper peat layer to oxygen, leading to elevated decomposition rates and net soil carbon losses. Empirical studies indicate positive relationships between long-term water table (WT) depth and soil carbon loss rate in peatlands. These correlations potentially enable using WT depth as a proxy for soil carbon losses from peatland plantations. Here, we compile data from published research assessing WT depth and carbon balance in tropical plantations on peat. We model net carbon loss from subsidence studies, as well as soil respiration (heterotrophic and total) from closed chamber studies, as a function of WT depth. WT depth across all 12 studies and 59 sites is 67 20 cm (mean standard deviation). Mean WT depth is positively related to net carbon loss, as well as soil respiration rate. Our models explain 45% of net carbon loss variation and 45-63% of soil respiration variation. At a 70 cm WT depth, the subsidence model suggests net carbon loss of 20 tC ha−1 yr−1 (95% confidence interval (CI) 18-22 tC ha−1 yr−1) for plantations drained for >2 yr. Closed chamber-measured total soil respiration at this depth is 20 tC-CO2 ha−1 yr−1 (CI 17-24 tC-CO2 ha−1 yr−1) while heterotrophic respiration is 17 tC-CO2 ha−1 yr−1 (CI 14-20 tC-CO2 ha−1 yr−1), ∼82% of total respiration. While land use is not a significant predictor of soil respiration, WT depths are greater at acacia (75 16 cm) than oil palm (59 15 cm) sample sites. Improved spatio-temporal sampling of the full suite of peat soil carbon fluxes-including fluvial carbon export and organic fertilizer inputs-will clarify multiple mechanisms leading to carbon loss and gain, supporting refined assessments of the global warming potential of peatland drainage.
ISSN:1748-9326
1748-9326
DOI:10.1088/1748-9326/10/7/074006