Abstract
Natural wetlands are the single most important contributors of methane (CH 4) to the atmosphere. Recent research has shown that the deposition of sulfate (SO 4 2-) can substantially reduce the emission of this radiatively important gas from wetlands. However, the influence of temperature in regulating the extent of this effect is unclear. Peatlands also constitute an important store of sulfur (S), so understanding the effect of S deposition on S dynamics within this store is important if we are to understand the interaction. The effect of enhanced SO 4 2- deposition on CH 4 fluxes and S pools were investigated in peatland monoliths under controlled environment conditions. This enabled a close examination of effects at the onset of experimentally enhanced SO 4 2- deposition while examining temperature effects on the interaction. Experimentally enhanced S deposition at rates as small as 15kg SO 4 2-Sha -1year -1 suppressed CH 4 emissions by 30%. There was no increased suppression at larger deposition rates of simulated acid rain. Temperature affected the suppressive effect of the simulated acid rain. At low temperatures (down to 5°C), there was a greater proportional suppression than at higher temperatures (up to 20°C). Evidence suggests that populations of SO 4 2-reducing bacteria do not respond, as previously thought, to enhanced SO 4 2- supply with a 'boom' followed by a 'bust' and less recalcitrant S pools (SO 4 2- and S°) were depleted in the SO 4 2-treated peat, indicating enhanced S turnover. A significant proportion of the SO 4 2- from the treatment was taken up and stored as SO 4 2- in vascular plants, placing this mechanism as a potentially important seasonal regulator of peatland SO 4 2- availability.
Original language | English |
---|---|
Pages (from-to) | 141-162 |
Number of pages | 22 |
Journal | Biogeochemistry |
Volume | 71 |
Issue number | 2 |
DOIs | |
Publication status | Published - Nov 2004 |
Keywords
- Acid rain
- Climate
- Methane
- Peat
- Sulfate
- Wetland
ASJC Scopus subject areas
- Environmental Chemistry
- Water Science and Technology
- Earth-Surface Processes