Publication

Deadwood, long recognized as playing an important role in storing carbon and releasing it as CO2 in forest ecosystems, is more recently drawing attention for its potential role in the cycling of other greenhouse trace gases. Across three Northeastern and Central US forests, mean methane (CH4) concentrations in deadwood were 23 times atmospheric levels (43.0 mu L L-1 +/- 12.3; mean +/- SE), indicating a lower bound, mean radial wood surface area flux of similar to 6 x 10(-4) mu mol CH4 m(-2) s(-1). Site, decay class, log diameter, and species were all highly significant predictors of CH4 abundance in deadwood, and diameter and decay class interacted as important controls limiting CH4 concentrations in the smallest and most decayed logs. Nitrous oxide (N2O) concentrations were negatively correlated with CH4 (r(2) = -0.20, p < 0.001) and on average similar to 25 % lower than ambient (276.9 nL L-1 +/- 2.9; mean +/- SE), indicating net consumption of nitrous oxide. Oxygen (O-2) concentrations were uniformly near anaerobic (355.8 mu L L-1 +/- 1.2; mean +/- SE), and CO2 was elevated from atmospheric (9336.9 mu L L-1 +/- 600.6; mean +/- SE). Most notably, our observations that CH4 concentrations were highest in the least decayed wood, may suggest that methanogenesis is not fuelled by structural wood decomposition but rather by consumption of more labile nonstructural carbohydrates.