Nitrogen in Atmospheric Wet Depositions Over the East Indian Ocean and West Pacific Ocean: Spatial Variability, Source Identification, and Potential Influences

Jiang, Shan; Jin, Jie; Jiang, Shuo; Wu, Ying; Wang, Jianing; Chen, Ju; Zhang, Zhenqiu; Liu, Sumei; Chang, Yan; Wang, Lingyan; Zhang, Jing

doi:10.3389/fmars.2020.600843

Cited by 7 publications

(2 citation statements)

References 73 publications

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“…Atmospheric transport can be also a relevant source of POC to the tropical coast, particularly during fire events as black carbon (Liu et al, 2022) and aeolian dust, particularly in the tropical Atlantic originated from the Sahara and the Sahel (Eglinton et al, 2002;Ibańhez et al, 2022). The high temperature of tropical zones further enhances coastal ventilation and terrestrial volatile compounds are rapidly spread through Walker Circulation to long distances from the source (Jiang et al, 2021a). The in-situ production of DOC and POC in tropical coastal ecosystems mainly due to the activity of different primary producers is also a large source of organic carbon due to the general high productivity of tropical coasts (Figure 1A).…”

Section: Organic Carbon Cycling In Tropical Coastsmentioning

confidence: 99%

Exploring feedback mechanisms for nitrogen and organic carbon cycling in tropical coastal zones

Jiang

Jin

et al. 2022

Front. Mar. Sci.

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The anthropogenic introduction of significant amounts of reactive nitrogen in the coastal zone particularly since the discovery and application of the Haber-Bosch process has profound consequences over organic carbon storage and transformations at both regional and global scales. Here, we review our current knowledge on cause-effect chains for nitrogen, especially dissolved inorganic nitrogen, on organic carbon cycling in coastal tropical systems. We focus on the feedback mechanisms for turnover of different organic carbon species to nitrogen excess and links to current environmental and climate changes. We pay special attention to organic carbon dynamics in tropical coasts due to their high primary productivity, rapid sedimentation, and significant needs of nitrogen for agriculture and industry usages. Together with land-use changes and economy development, we highlight the vulnerability of carbon storage in tropical coasts triggered by nitrogen overloading and outline possible industrial strategies with low carbon cycling disturbance to benefit the development of tropical countries.

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Section: Organic Carbon Cycling In Tropical Coastsmentioning

confidence: 99%

Exploring feedback mechanisms for nitrogen and organic carbon cycling in tropical coastal zones

Jiang

Jin

et al. 2022

Front. Mar. Sci.

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“…In addition, the spectral slope from 275 to 295 nm was determined as a proxy of the molecular weight of CDOM (S 275−295 ; terrestrial materials frequently show small slopes, while pelagic materials tend to show larger slopes; Zhang et al, 2007). The isotopic composition of NO 3 − (δ 15 N/ 18 O-NO 3 − ) was determined in the collected samples to understand reaction pathways and rates in place (Jiang et al, 2019(Jiang et al, , 2021b. The isotopic ratios were measured by the bacterial reduction method (Sigman et al, 2001) using a Thermo-Fisher Delta V advantage analyzer coupled with a PreCon system (more details in Jin et al, 2020…”

Section: Water Analysesmentioning

confidence: 99%

Response of Nitrate Processing to Bio-labile Dissolved Organic Matter Supply Under Variable Oxygen Conditions in a Sandy Beach Seepage Face

Jiang

Jin

et al. 2021

Front. Mar. Sci.

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Supply of bio-labile dissolved organic matter (DOM) has been assumed to be a key factor for the intensity of nitrate (NO3–) removal in permeable coastal sediments. In the present study, a series of flow through reactor experiments were conducted using glucose as a N-free bio-labile DOM source to permeable sediments from a sandy beach seepage face to identify its effect on benthic NO3– removal. The results revealed a shift from the dominance of NO3– production to removal processes when NO3– input concentration increased from 10 to 80 μM under oxic conditions. Sediment microbiota information suggests that nitrification (e.g., Nitrosomonas and Nitrososphaera) and denitrification (e.g., Marinobacter and Bacillus) were dominant pathways for benthic NO3– production and removal in the studied sediment. Compared with the active response of sediment microbiota to NO3– additions, the supply of glucose (approximately 300 μM final concentration added) did not significantly change the NO3– removal efficiency under aerobic conditions (dissolved oxygen saturation approximately 100%). Similarly, an insignificant increase of NO3– removal rate after glucose amendment of the circulating water was obtained when dissolved oxygen (DO) saturation decreased to approximately 70% in the input solution. When DO at the input solution was decreased to 30% saturation (sub-oxic conditions), the removal rate of NO3– in the group amended with glucose increased, suggesting that glucose stimulated denitrifiers. These results revealed that NO3– removal relied mainly on the anaerobic environment at particle surfaces, with a dependence on the sedimentary organic matter as an electron supplier under bulk aerobic conditions, while the bio-labile DOM was consumed mainly by aerobic respiration instead of stimulating NO3– reduction. However, the respiration triggered by the over-supply of bio-labile DOM reduced the DO in the porewater, likely depressing the activity of aerobic reactions in the permeable sediment. At this point, the benthic microbiota, especially potential denitrifiers, shifted to anaerobic reactions as the key to support nitrogen metabolism. The glucose amendment benefited NO3– reduction at this point, under sub-oxic conditions.

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Nutrient cycling in tropical and temperate coastal waters: Is latitude making a difference?

Lønborg

Müller

Butler

et al. 2021

Estuarine, Coastal and Shelf Science

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Nitrogen in Atmospheric Wet Depositions Over the East Indian Ocean and West Pacific Ocean: Spatial Variability, Source Identification, and Potential Influences

Cited by 7 publications

References 73 publications

Exploring feedback mechanisms for nitrogen and organic carbon cycling in tropical coastal zones

Exploring feedback mechanisms for nitrogen and organic carbon cycling in tropical coastal zones

Response of Nitrate Processing to Bio-labile Dissolved Organic Matter Supply Under Variable Oxygen Conditions in a Sandy Beach Seepage Face

Nutrient cycling in tropical and temperate coastal waters: Is latitude making a difference?

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