Elucidating the mechanisms of nitrogen retention in forests is essential for the evaluation of ecosystem functioning in forests under environmental changes (e.g., increasing nitrogen deposition). We measured δ¹⁵N and ¹⁵N recovery in each pool of vegetation and soil 10 years after the addition of ¹⁵N tracer in a red pine forest in the northern Kanto region exposed to high load of atmospheric N deposition to determine its fate. The long-term effect of atmospheric N deposition was evaluated by comparing ¹⁵N recovery 10 years and 1 year after its addition.
The experiment was conducted in a red pine forest at Akagi Testing Center of Central Research Institute of Electric Power Industry located in the Gunma prefecture. We set plots of ¹⁵N addition and control (20 m²) and sprayed ammonium chloride solution labelled with ¹⁵N (0.5 kgN ha^-1) in the former plot. In January 2013, 10 years after the ¹⁵N addition, the aboveground parts of the red pine trees (discs of trunks, branches, leaves, and cones); O layer (mostly organic matter); and soil samples at 0–10, 10–20, and 20–40 cm depth along with fine roots were collected. The δ¹⁵N was analyzed using a mass spectrometer and its recovery was calculated for each pool by dividing the ¹⁵N amount in the pool, which was calculated from biomass or content, N concentration, and δ¹⁵N, by the added ¹⁵N amount.
The δ¹⁵N of each part of the trees was significantly higher in plots where ¹⁵N was added than in the control plot. The tree ring formed by separation of the xylem after every 5 years during the last 15 years did not affect δ¹⁵N. δ¹⁵N of other organs of trees was higher in plots with added ¹⁵N than in the control plot. The δ¹⁵N in each organ showed that fine roots registered the highest (9.7–10.0‰) values, whereas other organs had negative values. This was probably attributed to ¹⁵N dilution due to the larger nitrogen pool in the aboveground parts. On the other hand, δ¹⁵N of each tree organ was considerably lower than that collected 1 year after ¹⁵N addition, indicating that ¹⁵N was diluted and moved to the O layer pool due to the mortality of leaves and fine roots and gradually replaced natural nitrogen (¹⁴N). The δ¹⁵N of the O layer and soil was higher in plots with added ¹⁵N, and maximum value was observed at 0–10-cm depth. The δ¹⁵N of the O layer dramatically decreased compared to that collected 1 year after ¹⁵N addition. This might be attributed to rapid litter decomposition and lower δ¹⁵N in the newly supplied litter. The δ¹⁵N of the soil was similar to that collected 1 year after ¹⁵N addition. ¹⁵N recovery in the trees and O layers was 2% and 0.2%, respectively, suggesting that the deposited nitrogen did not accumulate in the vegetation and moved to the soil in the long-run. On the other hand, sum of ¹⁵N recovery in the soil was 32%, accounting for the majority of ¹⁵N recovery in the whole ecosystem (34%). There was no decrease in the ¹⁵N recovery in the soil compared to that 1 year after ¹⁵N addition. This study demonstrated that soil, rather than vegetation or the O layer, plays an important role in retaining N in the forest ecosystem from a long-term viewpoint. Furthermore, a decline in tree biomass due to pine wilt disease would accelerate the reduction in the function of nitrogen retention by vegetation via decreased uptake/transportation and decreased nitrogen pool. However, ¹⁵N recovery in the whole ecosystem decreased from 84% to 34% during 9 years from 1 year to 10 years after ¹⁵N addition, implying that a substantial amount of nitrogen was lost from the forest soil.