Nitrogen mineralization and immobilization in sediments of the East China Sea: Spatiotemporal variations and environmental implications

Lin, Xianbiao; Hou, Lijun; Liu, Min; Li, Xiaofei; Yin, Guoyu; Gao, Juan; Jiang, Xiaofen

doi:10.1002/2016jg003499

Cited by 54 publications

(35 citation statements)

References 78 publications

(145 reference statements)

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“…The measured rates (0.39 to 7.74 nmol N g −1 dry sediment hr −1 ) of nitrogen fixation in this study are comparable to the values reported from other estuarine and coastal sediments (Table ), and the rates are much lower than the denitrification rates (12.04 to 67.13 nmol N g −1 dry sediment hr −1 ) while approximately equivalent to the anammox rates (0.94 to 6.61 nmol N g −1 dry sediment hr −1 ) in the study area (Hou et al, ). If the annual mean rate (1.65 nmol N g −1 dry sediment hr −1 ) of sediment nitrogen fixation obtained in this study is extrapolated to the entire Yangtze Estuary, it is roughly estimated that approximately 1.02 × 10 5 t of nitrogen was fixed annually into the estuarine and coastal environment, given that the bulk density of dry sediment is about 1.19 g cm −3 (Lin et al, ). This calculated amount accounts for about 9.3% of the terrigenous inorganic nitrogen (1.1 × 10 6 t) transported annually into the Yangtze Estuary (Hou et al, ).…”

Section: Discussionmentioning

confidence: 85%

Nitrogen Fixation in the Intertidal Sediments of the Yangtze Estuary: Occurrence and Environmental Implications

et al. 2018

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Nitrogen fixation is a microbial‐mediated process converting atmospheric dinitrogen gas to biologically available ammonia or other molecules, and it plays an important role in regulating nitrogen budgets in coastal marine ecosystems. In this study, nitrogen fixation in the intertidal sediments of the Yangtze Estuary was investigated using nitrogen isotope tracing technique. The abundance of nitrogen fixation functional gene (nifH) was also quantified. The measured rates of sediment nitrogen fixation ranged from 0.37 to 7.91 nmol N g−1 hr−1, while the abundance of nifH gene varied from 2.28 × 106 to 1.28 × 108 copies g−1 in the study area. The benthic nitrogen fixation was correlated closely to the abundance of nifH gene and was affected significantly by salinity, pH, and availability of sediment organic carbon and ammonium. It is estimated that sediment nitrogen fixation contributed approximately 9.3% of the total terrigenous inorganic nitrogen transported annually into the Yangtze estuarine and coastal environment. This result implies that the occurrence of benthic nitrogen fixation acts as an important internal source of reactive nitrogen and to some extent exacerbates nitrogen pollution in this aquatic ecosystem.

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Section: Discussionmentioning

confidence: 85%

Nitrogen Fixation in the Intertidal Sediments of the Yangtze Estuary: Occurrence and Environmental Implications

et al. 2018

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“…Temperature is an important factor regulating nitrogen transformations, because it affects microbial metabolism directly (Grenon et al, ). The warm season favors the activities of these nitrogen transforming microbes (Jäntti et al, ; Lan et al, ; Lin, Hou, Liu, Li, Zheng, et al, ; Teal et al, ). Interestingly, previous studies reported that temperature is not an important factor controlling the DNRA activity in marine and estuarine sediments (Deng et al, ; Jäntti et al, ; Lisa et al, ; McTigue et al, ), but other studies suggest that higher temperatures enhance DNRA rates in coastal and lacustrine sediments (Brin et al, ; Gardner et al, ; Giblin et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…Gross nitrogen mineralization and NH 4 + immobilization rates were related positively to Eh of overlying water (Table ), mainly because nitrogen mineralization and NH 4 + immobilization processes often occur under aerobic conditions (Updegraff et al, ; Zhou et al, ). NO 3 − is a significant factor regulating the gross nitrogen mineralization because it is an electron acceptor that can oxidate the organic material in aerobic conditions (Lin, Hou, Liu, Li, Zheng, et al, ; Pena et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…Subsequently, one half of the vials were sacrificed immediately by addition of 100 μL saturated HgCl 2 , and the remaining vials were incubated in the dark at in situ temperature for 12 h on a shaker table (150 rpm/min) and then stopped by HgCl 2 , and the vials were incubated 12 h. The generated 15 NH 4 + of 0 and 12 h incubations were determined by OX/MIMS (Yin et al, ). The potential rates of nitrogen fixation were calculated by the following equation:

F = \frac{italicHf - italicHi}{t}

where F (μg N g −1 d −1 ) is the potential rates of nitrogen fixation, H i and H f (μg N g −1 ) are the respective concentrations of 15 NH 4 + in initial and final sediment slurries, and t (d) is the time of incubation.The gross nitrogen mineralization and NH 4 + immobilization rates were determined using the nitrogen isotope dilution technique, as described by Lin, Hou, Liu, Li, Zheng, et al (). Slurries were made and preincubated as described above.…”

Section: Methodsmentioning

confidence: 99%

“…NH 4 + was then extracted with 2 M KCl from the initial and final sediment slurries (Lin, Hou, Liu, Li, Yin, et al, ). After extraction, the total NH 4 + ( 14 NH 4 + plus 15 NH 4 + ) in extractants were analyzed by a continuous‐flow nutrient autoanalyzer, and the 15 NH 4 + determined by OX/MIMS (Lin, Hou, Liu, Li, Yin, et al, and Lin, Hou, Liu, Li, Zheng, et al, ; Yin et al, ). Gross nitrogen mineralization and NH 4 + immobilization rates were quantified as described previously (Lin, Hou, Liu, Li, Yin, et al, and Lin, Hou, Liu, Li, Zheng, et al, ).…”

Section: Methodsmentioning

confidence: 99%

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Ammonium Production and Removal in the Sediments of Shanghai River Networks: Spatiotemporal Variations, Controlling Factors, and Environmental Implications

Lin

Gao

et al. 2017

JGR Biogeosciences

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Ammonium (NH4+) pollution and associated processes causing environmental problems in aquatic ecosystems have attracted much attention. However, the microbial pathways of NH4+ production and removal and associated influencing factors in the sediments of urban rivers remain unclear. In this study, microbial pathways of NH4+ production and removal were quantified to examine the NH4+ balance in the sediments of Shanghai river networks. The results indicated that potential rates of gross nitrogen mineralization, dissimilatory nitrate reduction to ammonium, and nitrogen fixation ranged from 0.25 to 25.83 μg N g−1 d−1, from undetectable to 3.47 μg N g−1 d−1, and from 0.07 to 3.05 μg N g−1 d−1, respectively. The potential rates of gross NH4+ immobilization, anammox, and nitrification, as the NH4+ removal processes, ranged from 0.24 to 26.27 μg N g−1 d−1, from 0.01 to 7.97 μg N g−1 d−1, and from 0 to 9.62 μg N g−1 d−1, respectively. Temperature, dissolved oxygen, NO3−, NH4+, and total organic carbon had great influences on these NH4+ production and removal processes. In addition, the total amounts of NH4+ production and removal through microbial pathways in sediments of Shanghai river networks were estimated at approximately 2.6 × 105 t N yr−1 and 3.9 × 105 t N yr−1, respectively. Thus, the net sink of NH4+ was 1.3 × 105 t N yr−1, which accounts for 22% of total inputs of nitrogen in the river networks. These results indicate that microbial processes of removal in sediments can eliminate significant parts of NH4+ generated from microbial pathways and/or inputs from anthropogenic activities in urban rivers. Overall, these results improve understanding of NH4+ production and removal and associated influencing environmental factors and highlight the environmental importance of these processes in regulating the NH4+ budget in highly urbanized riverine ecosystems.

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Distribution pattern and mass budget of sedimentary polycyclic aromatic hydrocarbons in shelf areas of the Eastern China Marginal Seas

et al. 2017

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This study conducted the first extensive and comprehensive investigation of the regional‐scale sedimentary polycyclic aromatic hydrocarbons (PAHs) concentration, flux, and budget in the continental shelves of the Eastern China Marginal Seas (ECMSs). Surface sediment samples from multiple sites were collected and assessed, and the latest data from current research were assessed. The spatial distribution pattern of PAHs in the ECMSs was significantly influenced by the regional hydrodynamics, sediment properties (grain‐size, total organic carbon [TOC] content, and sedimentation rate), and anthropogenic impacts. Relatively higher PAHs concentrations occurred in areas with fine‐grained sediment. Results of source apportionment found that the relative proportions of PAHs showed significant regional variation, mainly influenced by socioeconomic differences between north and south China. The PAHs burial flux in the study area ranged from 11.2 to 1308 ng cm−2 yr−1 with an average value of 101 ± 104 ng cm−2 yr−1. The area‐integrated sedimentary PAHs burial flux across the ECMSs was 494 t yr−1. A mass budget calculation revealed that riverine input and atmospheric deposition were the most significant sources contributing, 28.4% and 71.6%, respectively. The study demonstrated that net PAHs transportation occurs between the Bohai Sea (BS) and Yellow Sea (YS), with a flux of approximately 10.2 t yr−1. PAHs were also transported from YS to the East China Sea (ECS), due to water exchange between the YS and ECS. Additionally, substantial amounts of PAHs in the inner shelf of the ECS were transported out of the shelf area due to cross‐shelf plume.

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Nitrogen mineralization and immobilization in sediments of the East China Sea: Spatiotemporal variations and environmental implications

Cited by 54 publications

References 78 publications

Nitrogen Fixation in the Intertidal Sediments of the Yangtze Estuary: Occurrence and Environmental Implications

Nitrogen Fixation in the Intertidal Sediments of the Yangtze Estuary: Occurrence and Environmental Implications

Ammonium Production and Removal in the Sediments of Shanghai River Networks: Spatiotemporal Variations, Controlling Factors, and Environmental Implications

Distribution pattern and mass budget of sedimentary polycyclic aromatic hydrocarbons in shelf areas of the Eastern China Marginal Seas

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