Ecological risks in anthropogenic disturbance of nitrogen cycles in natural terrestrial ecosystems

Fujimaki, Reiji; Sakai, Akiko; Kaneko, Nobuhiro

doi:10.1007/s11284-008-0578-x

Cited by 28 publications

(18 citation statements)

References 103 publications

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“…The rapid growth since 1970 was largely driven by the emergence of a domestic N fertilizer industry and the intensive agriculture during the 1970s, and as a result, chemical fertilizer of 29 Tg N accounted for over one-half of Nr use in 2010. To a large extent, the impact of humans on the N cycle stems from their attempt to alleviate N deficiencies in agriculture by the application of fertilizer (7). Recently, the average N fertilizer application rate on Chinese cropland has reached 240 kg/ha per year.…”

Section: Resultsmentioning

confidence: 99%

“…Nr accumulation in different reservoirs has a wide variety of consequences, magnified with time as Nr moves along its biogeochemical pathways (6). These consequences result in a cascade of environmental changes, including smog, acid rain, forest dieback, coastal dead zones, biodiversity loss, stratospheric ozone depletion, and an enhanced greenhouse effect as well as health problems (5)(6)(7)(8). Currently, there is great interest in improving the efficiency of Nr use and balancing food production, energy consumption, and industrial needs with the aim of minimizing damages to environmental systems (9).…”

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confidence: 99%

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Centennial-scale analysis of the creation and fate of reactive nitrogen in China (1910–2010)

Cui

Shi

Groffman

et al. 2013

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

280

166

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Human mobilization and use of reactive nitrogen (Nr) has been one of the major aspects of global change over the past century. Nowhere has that change been more dramatic than in China, where annual net Nr creation increased from 9.2 to 56 Tg from 1910 to 2010. Since 1956, anthropogenic Nr creation exceeded natural Nr creation, contributing over 80% of total Nr until 2010. There is great interest and uncertainty in the fate and effects of this Nr in China. Here, a comprehensive inventory of Nr in China shows that Nr (including recycled Nr) has continuously and increasingly accumulated on land (from 17 to 45 Tg), accompanied by increasing transfers to the atmosphere (before deposition; from 7.6 to 20 Tg), inland waters (from 2.7 to 9.6 Tg), and coastal waters (from 4.5 to 7.7 Tg) over the past 30 y. If current trends continue, Nr creation from human activities will increase to 63 Tg by 2050, raising concerns about deleterious environmental consequences for land, air, and water at regional and global scales. Tremendous amounts of Nr have accumulated in plants, soils, and waters in China over the past 30 y, but the retention capacity of the terrestrial landscape seems to be declining. There is a possibility that the negative environmental effects of excessive Nr may accelerate in coming decades, increasing the urgency to alter the trajectory of increasing Nr imbalance. Here, a conceptual framework of the relationships between human drivers and Nr cycling in China is oriented and well-targeted to Chinese abatement strategies for Nr environmental impact.

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Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

Centennial-scale analysis of the creation and fate of reactive nitrogen in China (1910–2010)

Cui

Shi

Groffman

et al. 2013

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

280

166

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“…It has been reported that increasing N availability by N deposition has outweighed soil acidification caused by acid rain in some European (Emmett et al 1998) and North American forests, but little is known about Asian forests (Fujimaki et al 2009). Also, acidification impacts are not immediate, and it may be possible that increased N availability may not necessarily offset acidification impacts in the long term.…”

Section: Introductionmentioning

confidence: 99%

Impacts of enhanced nitrogen deposition and soil acidification on biomass production and nitrogen leaching in Chinese fir plantations

et al. 2012

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Atmospheric pollution levels in China are increasing quickly. Experience from other polluted regions shows that tree growth could be affected, but long-term effects of N deposition and soil acidification on Chinese forests remain mostly unknown. Soil acidification and N deposition were simulated for Chinese fir (Cunninghamia lanceolata (Lamb.) Hook.) plantations managed for three consecutive 20-year rotations in southeastern China. A factorial experiment combined four rain pH levels (2.5, 4.0, 5.6, and 7.0), four N deposition rates (1, 7.5, 15, and 30 kg N·ha -1 ·year -1 ), and two site qualities (poor and rich). Results indicate that atmospheric pollution effects are not immediate, but after one to two rotations, soil acidification effects could reduce ecosystem C pools significantly (-25% and -11% in poor and rich sites, respectively). N deposition rates above 15 kg N·ha -1 ·year -1 could offset some of the negative effects of soil acidification and lead to more ecosystem C (19 and 28 Mg C·ha -1 more in poor and rich sites, respectively, than in low N deposition). However, at high N deposition rates (>15 kg N·ha -1 ·year -1 ), N leaching losses could greatly increase, reaching 75 kg N·ha -1 ·year -1 . Moderate N deposition could increase tree biomass production and soil organic mass, resulting in increased ecosystem C, but these gains could be associated with important N leaching. Atmospheric pollution could also result in the long term in nutrient imbalances and additional ecological issues (i.e., biodiversity loss, eutrophication, etc.) not studied here.Résumé : Les niveaux de pollution atmosphérique augmentent rapidement en Chine. L'expérience d'autres régions aux prises avec la pollution montre que la croissance des arbres pourrait être ralentie mais les effets à long terme des dépôts azotés (N) et de l'acidification des sols dans les forêts chinoises sont pratiquement inconnus. L'acidification du sol et les dépôts de N ont été simulés dans des plantations de sapin de Chine (Cunninghamia lanceolata (Lamb.) Hook.) aménagées pendant trois rotations consécutives d'une durée de 20 ans dans le sud-est de la Chine. Une expérience factorielle a combiné quatre niveaux de pluie acide (pH 2,5, 4,0, 5,6 et 7,0), quatre taux de déposition de N (1, 7,5, 15 et 30 kg N·ha -1 ·an -1 ) et deux qualités de station (pauvre et riche). Les résultats montrent que les effets de la pollution atmosphérique ne sont pas immé-diats, mais qu'après une à deux rotations, les effets de l'acidification du sol pouvaient réduire de façon significative les ré-serves de carbone (C) de l'écosystème (-25 et -11 % respectivement dans les stations pauvres et riches). Les taux de déposition de N plus élevés que 15 kg N·ha -1 ·an -1 pouvaient atténuer certains des effets négatifs de l'acidification du sol et ont mené à plus de C de l'écosystème (19 et 28 Mg C·ha -1 de plus respectivement dans les stations pauvres et riches qu'avec un faible taux de déposition de N). Cependant, les pertes de N par lessivage pouvaient augmenter de façon importante, ju...

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“…Nevertheless, the rapid loss of the original mineral P should cause a shortage of bioavailable P for montane ecosystems in the short-term, compared with the relatively flat region Syers 1976, Vitousek et al, 2010;Eger et al, 2011;Vincent et al, 2013). On the other hand, N deposition has dramatically increased in terrestrial ecosystems (Pardo et al, 2011;Fujimaki et al, 2009), which might decrease microbial biomass (Treseder, 2008) and change litter decomposition (Knorr et al, 2005). The P in microbial biomass was regarded as the major P pool (Turner et al, 2013), while the litter decomposition was an important avenue for P return (Fillippelli, 2008).…”

Section: Was P Lost During the 120 Years Of Pedogenesis?mentioning

confidence: 99%

Rapid loss of phosphorus during early pedogenesis along a glacier retreat choronosequence, Gongga Mountain (SW China)

Zhou

Bing

et al. 2015

Preprint

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The loss of phosphorus (P) during the early pedogenesis stage is important at the ecosystem level, and it also plays an important role in the global P cycle. The seasonal variation of total P (Pt) and its fractions along a young soil chronosequence (Hailuogou chronosequence) on the eastern slope of Gongga Mountain, SW China, was investigated based on the modified Hedley fractionation technique to understand P loss during the early pedogenesis stage. The results showed that the mineral P (mainly apatite) was the dominant fraction of Pt in the C horizon of the soil, and the seasonal difference in Pt and its fractions was insignificant. In the A horizon, Pt concentrations decreased markedly compared with those in the C horizon, and as the age of the soil increased, the inorganic P (Pi) significantly decreased and the organic P (Po) prominently increased. Seasonally, the P fractions exhibited various distributions in the A horizon. The variation of Pt and its fractions revealed that the P loss was rapid along the 120-year soil chronosequence. The concentrations of Pt in the original minerals decreased more than 50% in the 52 years since the glacier retreated, and the depletion reached almost 80% at the 120-year pedogenesis. The loss of P from the soil of the Hailuogou chronosequence was mainly attributed to weathering, plant uptake, and transport by runoff. The data obtained indicated that the glacier retreat chronosequence could be used to elucidate the fast rate of P loss during the early pedogenesis stage. Abstract The loss of phosphorus (P) during the early pedogenesis stage is important at the ecosystem level, and it also plays an important role in the global P cycle. The seasonal variation of total P (Pt) and its fractions along a young soil chronosequence (Hailuogou chronosequence) on the eastern slope of Gongga Mountain, SW China, was investigated based on the modified Hedley fractionation technique to understand P loss during the early pedogenesis stage. The results showed that the mineral P (mainly apatite) was the dominant fraction of Pt in the C horizon of the soil, and the seasonal difference in Pt and its fractions was insignificant. In the A horizon, Pt concentrations decreased markedly compared with those in the C horizon, and as the age of the soil increased, the inorganic P (Pi) significantly decreased and the organic P (Po) prominently increased. Seasonally, the P fractions exhibited various distributions in the A horizon. The variation of Pt and its fractions revealed that the P loss was rapid along the 120-year soil chronosequence. The concentrations of Pt in the original minerals decreased more than 50% in the 52 years since the glacier retreated, and the depletion reached almost 80% at the 120-year pedogenesis. The loss of P from the soil of the Hailuogou chronosequence was mainly attributed to weathering, plant uptake, and transport by runoff. The data obtained indicated that the glacier retreat chronosequence could be used to elucidate the fast rate of P loss during the early pedogenesis sta...

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Ecological risks in anthropogenic disturbance of nitrogen cycles in natural terrestrial ecosystems

Cited by 28 publications

References 103 publications

Centennial-scale analysis of the creation and fate of reactive nitrogen in China (1910–2010)

Centennial-scale analysis of the creation and fate of reactive nitrogen in China (1910–2010)

Impacts of enhanced nitrogen deposition and soil acidification on biomass production and nitrogen leaching in Chinese fir plantations

Rapid loss of phosphorus during early pedogenesis along a glacier retreat choronosequence, Gongga Mountain (SW China)

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