CO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; emissions from peat-draining rivers regulated by water pH

Klemme, Alexandra; Rixen, Tim; Müller-Dum, Denise; Müller, Moritz; Notholt, Justus; Warneke, Thorsten

doi:10.5194/bg-19-2855-2022

Cited by 4 publications

(1 citation statement)

References 57 publications

(106 reference statements)

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“…Peatland drainage instigates deterioration, which is perceived as one of the factors contributing to the loss of C or the emission of GHGs from peat. The emission of CO2 from drained peat soils releases when the oxygenated uppermost layer of peat decomposes, whereas methane (CH4) can be engendered in the deeper, water-saturated stratum by methanogens and potentially oxidized in the oxygenated upper stratum by methane-oxidizing bacteria (Norberg et al, 2021;Klemme et al, 2022). In wetland soils, CH4 is produced in the anaerobic areas of submerged soils by methanogens.…”

Section: Introductionmentioning

confidence: 99%

Effect of peat water levels on greenhouse gas production in different cropping land use

Wihardjaka,

Teddy Sutriadi,

Adriany

et al. 2024

Chil. j. agric. res.

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Degraded peat has a high potential for use in agricultural production, especially food crops. The water table, which impacts the production of greenhouse gases (GHGs), is the main problem concerning peat utilization. The study aimed to determine the production of greenhouse gases at various peat water levels. The study was conducted in a laboratory setting utilizing the soil column of undisturbed peat soil. The factorial experiment was arranged in randomized block design, with three replicates, with the first factor was peat cropping use: Maize (Zea mays L.), pineapple (Ananas comosus (L.) Merr.), and scrubs. The second factor was water level (0, 10, 20, 30 cm depth). Variables measured were GHG flux (CO2 and CH4), pH, redox potential, total C content, and ash content. The peat cropping use interacted significantly with the peat water level on the potential for CH4 and CO2 production and the value of global warming potential. Water table depth significantly increased CO2 flux and global warming potential (GWP) in all three peat cropping uses. The lowest GWP at a 0 cm peat water level was 944 (pineapple use), 961 (maize use), and 1097 mg CO2e m -2 d -1 (scrub use). Peat for pineapple cultivation produces the lowest CO2 production and GWP compared to maize cultivation and scrubs. The negative relationship between redox potential and GWP is significant in peat for scrub. The relationship between pH and GWP is significant in peat for pineapple and scrub.

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Section: Introductionmentioning

confidence: 99%

Effect of peat water levels on greenhouse gas production in different cropping land use

Wihardjaka,

Teddy Sutriadi,

Adriany

et al. 2024

Chil. j. agric. res.

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Destabilization of carbon in tropical peatlands by enhanced weathering

Klemme

Rixen

Müller

et al. 2022

Commun Earth Environ

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Enhanced weathering is a carbon dioxide (CO2) removal strategy that accelerates the CO2 uptake and removal from the atmosphere by weathering via the dispersion of rock powder. Warm and humid conditions enhance weathering and among the suggested target areas for enhanced weathering are tropical peatlands. However, the effect of enhanced weathering on peatland carbon stocks is poorly understood. Here, we present estimates for the response of CO2 emissions from tropical peat soils, rivers and coastal waters to changing soil acidity induced by enhanced weathering application. We estimate that the potential carbon uptake associated with enhanced weathering is reduced by 18–60% by land-based re-emission of CO2 and is potentially offset completely by emissions from coastal waters. Our findings suggest that in contrast to the desired impact, enhanced weathering may destabilize the natural carbon cycle in tropical peatlands that act as important carbon sinks and protect against coastal erosion.

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Preliminary Assessment of Selected Physico-chemical Properties of Peat Water in Relation to Land Use Conversion in Leyte Sab-a Basin Peatland, Philippines

Salamia,

Decena,

Arguelles

et al. 2024

ATR

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Tropical peatlands are unique wetland ecosystems that provide various ecosystem services such as carbon and water storage. However, these ecosystems have been significantly altered by anthropogenic activities. In this study, the impact of land use conversion on the selected physico-chemical properties of surface water in the Leyte Sab-a Basin Peatland was investigated. Surface peat water was collected from peat swamp forest, peatland converted to grassland and peatland under cultivation. The surface peat water temperature was measured on-site and the collected water samples were analyzed for turbidity, pH, dissolved oxygen (DO), nitrate (NO3-N), phosphate (PO4), and total dissolved solids (TDS). It was found that the physico-chemical properties of water such as temperature, pH, and TDS were significantly higher in disturbed land use (cultivation) areas. The direct relationship between the temperature of surface peat water to both phosphate and TDS suggests that increasing temperature brought by peatland conversion may directly lead to increasing phosphate and total dissolved solids concentration in water. Strong relationships were also found between TDS and phosphates as well as between pH and dissolved oxygen. Finally, the increasing trend of values of the examined peat water physico-chemical properties with land use disturbance (cultivation) indicates peatland degradation.

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CO<sub>2</sub> emissions from peat-draining rivers regulated by water pH

Cited by 4 publications

References 57 publications

Effect of peat water levels on greenhouse gas production in different cropping land use

Effect of peat water levels on greenhouse gas production in different cropping land use

Destabilization of carbon in tropical peatlands by enhanced weathering

Preliminary Assessment of Selected Physico-chemical Properties of Peat Water in Relation to Land Use Conversion in Leyte Sab-a Basin Peatland, Philippines

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