Increasing nitrogen (N) deposition could alter nutrient balance in forest ecosystems and increase nitrate (NO₃⁻) leaching into stream, which may degrade water quality in downstream aquatic environment. Nitrogen deposition, microbial N transformation, and N uptake by plants and microbes create the complex dynamics of N in forest ecosystem, which makes it difficult to evaluate and predict the impacts of increasing N deposition on forest and aquatic ecosystems. Studies using ¹⁵N tracer to determine the fate of N inputs have improved our understandings on the retention, transformation, and leaching of N in forest floor and surface soils. Studies that examine the natural stable isotopes of the precipitation and stream water have given insights into N saturation status of forested catchments against excess atmospheric N deposition. In contrast, our understanding of the N dynamics in canopy-soil continuum is still limited. Measurement of triple oxygen isotope composition (Δ¹⁷O) of nitrate enables us to quantify the absolute values of atmospheric NO₃⁻ (NO₃⁻atm) concentration and flux with higher accuracy than the values estimated from δ¹⁸O of NO₃⁻. This makes it possible to trace NO₃⁻atm after it enters forest ecosystem. Therefore, we aimed to determine the fate of NO₃⁻atm from forest canopy to surface soil using Δ¹⁷O of NO₃⁻ as a tracer. We also examined whether plant species affect the fate of NO₃⁻atm in the forest.

This study was conducted in a cool-temperate broadleaved-coniferous mixed forest located in Uryu Experimental Forest of Hokkaido University, northern Hokkaido, Japan. We selected plots under canopies of four trees of Quecus crispula (Oak) and Picea grehnii (Fir) and within four canopy gaps exclusively dominated by dwarf bamboo, Sasa senanensis (Sasa), in a small watershed (ca. three ha) for water collection. Throughfall, litter leachate beneath Oa layer, and soil water at the depth of 10 cm were collected in each plot. Litter leachate and soil water were collected by tension-free lysimeter. Bulk precipitation was collected in a large canopy gap next to the watershed. Water samples were collected after a single rain event in June, September, and October in 2014, and analyzed for inorganic N concentrations and stable isotopic compositions of NO₃⁻ (δ¹⁵N, δ¹⁸O, Δ¹⁷O). The stable isotopic compositions of the nitrate were determined using Continuous-Flow Isotope Ratio Mass Spectrometry (CF-IRMS) system in Nagoya University (Tsunogai et al., 2010). The concentration and flux of NO₃⁻atm were calculated from NO₃⁻ concentration, Δ¹⁷O value, and sample water volume.

The average Δ¹⁷O value of precipitation was +23.9 ‰. The average Δ¹⁷O values of the throughfall were lower than that of precipitation, and were lower under Oak (+17.7 ‰) and Fir (+18.9 ‰) than under Sasa (+23.3 ‰). These results indicate the occurrence of microbial nitrification on the plant canopies and the magnitude of nitrification in Oak and Fir canopies is larger than in Sasa canopy. The litter leachate and the soil water showed much lower Δ¹⁷O value of +2.3 ‰ and +1.4 ‰, respectively. This indicates that remineralizaed NO₃⁻ in soil becomes dominant in the leaching NO₃⁻ after passing the forest floor, but NO₃⁻atm still exist after passing the forest floor and surface soil where biological activity is very active. The average fluxes of NO₃⁻atm decreased from 0.84 mgN m⁻² rain day⁻¹ in the precipitation to 0.26 mgN m⁻² rain day⁻¹ in the soil water. The decrease of NO₃⁻atm was larger between precipitation and throughfall than between throughfall and litter leachate or soil water. More than 50 % of NO₃⁻atm in the precipitation was retained or consumed in the canopy, suggesting that forest canopy has a large influence on the fate of NO₃⁻atm in forest ecosystem. Overall, our results suggest that retention of deposited N in the forest canopy is significant and N dynamics in the forest canopy may be very different among plant species.