NITROGEN CYCLING IN TROPICAL PLANTATION FORESTS: POTENTIAL CONTROLS ON NITROGEN RETENTION: Fid-Bau Portal

NITROGEN CYCLING IN TROPICAL PLANTATION FORESTS: POTENTIAL CONTROLS ON NITROGEN RETENTION

Silver, W. L. / Thompson, A. W. / Reich, A. / Ewel, J. J. / Firestone, M. K.

The establishment and management of tropical plantations has the potential to significantly alter patterns in nitrogen (N) cycling relative to old‐growth tropical forests, which are generally characterized by high N availability and large fluxes of nitrous oxide (N₂O), an important greenhouse gas. We used ¹⁵N tracer additions to examine the effects of plantation establishment and management on gross N‐cycling rates, N retention via microbial assimilation and dissimilatory nitrate (NO₃⁻) reduction to ammonium (NH₄⁺) (DNRA), and N losses via N₂O emissions. In general, plantations had lower rates of N cycling and increased potential for N losses compared to old‐growth forests, but there were few differences between very short (one‐year) rotation and 10‐yr‐old uncut plantations. Gross N mineralization declined by almost 50% in the plantations compared to the old‐growth forests, and much of the mineralized N was nitrified at all sites. Gross nitrification rates were more variable and did not differ between old‐growth forests and unfertilized plantations; however, fertilization increased gross nitrification by a factor of 6 in short‐rotation forests, signaling a potential mechanism for increased N losses via leaching and gaseous emissions. Old‐growth forests had significantly higher microbial biomass N and NH₄⁺ assimilation rates. No microbial N assimilation was measured in the plantation soils, nor was there evidence of gross NH₄⁺ immobilization from estimates of NH₄⁺ consumption and nitrification. Plantations and old‐growth forests had similar DNRA rates (0.23 μg·g⁻¹·d⁻¹), which retains N in the ecosystem, and plantations had lower N₂O emissions. Nitrous oxide fluxes from plantations were highly sensitive to reducing conditions, highlighting the potential for high rates of N₂O losses. Our results show that plantation establishment can decrease rates of N cycling, but once forests are converted to plantations, internal N‐cycling pathways and N₂O fluxes are relatively resistant to disturbance associated with short rotation length.