Heterogeneous Atmospheric Nitrogen Deposition Effects Upon the Nitrate Concentration of Stream Waters in a Forested Mountain Area

Tabayashi, Yu; Koba, Keisuke

doi:10.1007/s11270-010-0519-5

Cited by 13 publications

(16 citation statements)

References 34 publications

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“…In the present study, about 25% of samples were greater than 1 mg-N L −1 as , which was a larger distribution ratio than that in Japan-wide monitoring 25 . Such high N concentration samples in the study region are comparable with values in European forest 17 , 18 and the same Kanto-region forest catchment reported to have N-saturated forests 25 – 27 . However, contrary to the European forests, pH in 99% of samples were >6.5, suggesting streams without acidification despite relatively high acid deposition loadings.…”

Section: Resultssupporting

confidence: 85%

Varying sensitivity of mountainous streamwater base-flow $${\bf{N}}{{\bf{O}}}_{{\bf{3}}}^{-}$$concentrations to N deposition in the northern suburbs of Tokyo

Nishina

Watanabe

Koshikawa

et al. 2017

Sci Rep

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Ecosystems of suburban landscapes (i.e., forest, inland water ecosystem) are threatened by high nitrogen (N) loadings derived from urban air pollutants. Forest ecosystems under high chronic N loadings tend to leach more N via streams. In the northern suburbs of Tokyo, N deposition loading on terrestrial ecosystems has increased over the past 30 years. In this region, we investigated nitrate concentrations in 608 independent small forested catchment water samples from northeastern suburbs of Tokyo. The nitrate concentrations varied from 0.07 to 3.31 mg-N L−1 in this region. We evaluated the effects of N deposition and catchment properties (e.g., meteorological and topographic factors, vegetation and soil types) on nitrate concentrations. In the random forest model, simulated N deposition rates from an atmospheric chemistry transportation model explained most of the variance of nitrate concentration. To evaluate the effects of afforestation management in the catchment, we followed a model-based recursive partitioning method (MOB). MOB succeeded in data-driven identification of subgroups with varying sensitivities to N deposition rate by vegetation composition in the catchment. According to MOB, the catchment with dominant coniferous coverage that mostly consisted of plantation with old tree age tended to have strong sensitivity of nitrate concentrations to N deposition loading.

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Section: Resultssupporting

confidence: 85%

Varying sensitivity of mountainous streamwater base-flow $${\bf{N}}{{\bf{O}}}_{{\bf{3}}}^{-}$$concentrations to N deposition in the northern suburbs of Tokyo

Nishina

Watanabe

Koshikawa

et al. 2017

Sci Rep

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“…S2 ), including one tropical and four subtropical sites in southwestern China; nine temperate sites in central, southern, and western Japan; and four Arctic tundra sites in northern Alaska. Among them, Tsukuba Forest Experimental Watershed (TKB) and Tama-Kyuryo Field Museum upper slope (TMU) and lower slope (TML) ( SI Appendix , Table S1 ) are characterized by high soil NO 3 − or N saturation ( 49 , 64 , 65 ), while the Arctic sites TFS, Sagavanirktok River Valley (SAG), and IMT ( SI Appendix , Table S1 ) are characterized by unmeasurable nitrification rates and negligible soil NO 3 − and, thus, are assumed to be typically low-NO 3 − ecosystems ( SI Appendix , Fig. S2 ).…”

Section: Methodsmentioning

confidence: 99%

Nitrate is an important nitrogen source for Arctic tundra plants

Liu

Koba

Koyama

et al. 2018

Proc. Natl. Acad. Sci. U.S.A.

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108

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SignificanceHow terrestrial plants use N and respond to soil N loading is central to evaluating and predicting changing ecosystem structure and function with climate warming and N pollution. Here, evidence from NO3− in plant tissues has uncovered the uptake and assimilation of soil NO3− by Arctic tundra plants, which has long been assumed negligible. Soil NO3− contributed about one-third of the bulk N used by tundra plants of northern Alaska. Accordingly, the importance of soil NO3− for tundra plants should be considered in future studies on N and C cycling in Arctic ecosystems where C sequestration is strongly determined by N availability.

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“…As the growing season coincides with the rainy season in Japan, greater nitrate export observed during this season likely reflects the combined influence of increased microbial nitrate production and high water drainage [ Mitchell et al ., ; Mitchell , ]. In a study of forested catchments near Tokyo, Tabayashi and Koba [] reported higher stream nitrate concentrations and δ 18 O‐

{NO}_{3}^{-}

values in areas receiving elevated N deposition inputs. However, maximum δ 18 O‐

{NO}_{3}^{-}

values only reached +6‰, showing that nitrification sources dominated stream nitrate even in catchments with high stream nitrate concentrations.…”

Section: Major Drivers Influencing Atmospheric Nitrate Transport In Cmentioning

confidence: 99%

Drivers of atmospheric nitrate processing and export in forested catchments

Rose

Sebestyen

Elliott

et al. 2015

Water Resources Research

Self Cite

104

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Increased deposition of reactive atmospheric N has resulted in the nitrogen saturation of many forested catchments worldwide. Isotope-based studies from multiple forest sites report low proportions (mean 5 10%) of unprocessed atmospheric nitrate in streams during baseflow, regardless of N deposition or nitrate export rates. Given similar proportions of atmospheric nitrate in baseflow across a variety of sites and forest types, it is important to address the postdepositional drivers and processes that affect atmospheric nitrate transport and fate within catchments. In a meta-analysis of stable isotope-based studies, we examined the influence of methodological, biological, and hydrologic drivers on the export of atmospheric nitrate from forests. The d values tended to increase with increasing baseflow discharge at all sites examined. To explain these differences, we present a conceptual model of hydrologic flowpath characteristics (e.g., saturation overland flow versus subsurface stormflow) that considers the influence of topography on landscape-stream hydrologic connectivity and delivery of unprocessed atmospheric nitrate to streams. Methodological biases resulting from differences in sampling frequency and stable isotope analytical techniques may further influence the perceived degree of unprocessed atmospheric nitrate export. Synthesis of results from numerous isotope-based studies shows that small proportions of unprocessed atmospheric nitrate are common in baseflow. However, hydrologic, topographic, and methodological factors are important drivers of actual or perceived elevated contributions of unprocessed atmospheric nitrate to streams.

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Heterogeneous Atmospheric Nitrogen Deposition Effects Upon the Nitrate Concentration of Stream Waters in a Forested Mountain Area

Cited by 13 publications

References 34 publications

Varying sensitivity of mountainous streamwater base-flow $${\bf{N}}{{\bf{O}}}_{{\bf{3}}}^{-}$$concentrations to N deposition in the northern suburbs of Tokyo

Varying sensitivity of mountainous streamwater base-flow $${\bf{N}}{{\bf{O}}}_{{\bf{3}}}^{-}$$concentrations to N deposition in the northern suburbs of Tokyo

Nitrate is an important nitrogen source for Arctic tundra plants

Drivers of atmospheric nitrate processing and export in forested catchments

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