Tropical peatlands play an important role in the global carbon cycling but little is known about factors regulating carbon dioxide (CO 2 ) and methane (CH 4 ) fluxes from these ecosystems. Here, we test the hypotheses that (i) CO 2 and CH 4 are produced mainly from surface peat and (ii) that the contribution of subsurface peat to net C emissions is governed by substrate availability. To achieve this, in situ and ex situ CO 2 and CH 4 fluxes were determined throughout the peat profiles under three vegetation types along a nutrient gradient in a tropical ombrotrophic peatland in Panama. The peat was also characterized with respect to its organic composition using 13 C solid state crosspolarization magic-angle spinning nuclear magnetic resonance spectroscopy. Deep peat contributed substantially to CO 2 effluxes both with respect to actual in situ and potential ex situ fluxes. CH 4 was produced throughout the peat profile with distinct subsurface peaks, but net emission was limited by oxidation in the surface layers. CO 2 and CH 4 production were strongly substrate-limited and a large proportion of the variance in their production (30% and 63%, respectively) was related to the quantity of carbohydrates in the peat. Furthermore, CO 2 and CH 4 production differed between vegetation types, suggesting that the quality of plant-derived carbon inputs is an important driver of trace gas production throughout the peat profile. We conclude that the production of both CO 2 and CH 4 from subsurface peat is a substantial component of the net efflux of these gases, but that gas production through the peat profile is regulated in part by the degree of decomposition of the peat. , 2010). In areas of the tropics which are expected to experience reduced rainfall and more prolonged drought (Meehl et al., 2007), peatlands may become less important sources of atmospheric methane (CH 4 ). However, this would be offset by greatly increased rates of aerobic decomposition and carbon dioxide (CO 2 ) release, with the result that their combined global warming potential would increase (Hirano et al., 2009;Couwenberg et al., 2010;Sjö gersten et al., 2010). It is also plausible that old C stored deep in the peat profile would be metabolized if climatic conditions become more favourable for decomposition, as has been reported for northern peatlands (e.g. Dorrepaal et al., 2009). In tropical environments, a substantial draw down of the water table would be required to impact deep peat layers. Considerable variation in C fluxes occurs between vegetation types in tropical wetland systems (Melling et al., 2005a, b;Sjö gersten et al., 2010), suggesting that C inputs from the vegetation (Sebacher et al., 1985;Joabsson & Christensen, 2001;Konnerup et al., 2010) are strong drivers of C fluxes in these systems. However, it is not known if these differences in C fluxes result mainly from surface processes or are maintained throughout the peat profile. Tropical peatlands may reach depths of up to 15 m (Phillips et al., 1997;Page et al., 1999Page...
