Aquaculture Production is a Large, Spatially Concentrated Source of Nutrients in Chinese Freshwater and Coastal Seas

Wang, Junjie; Beusen, Arthur; Liu, Xiaochen; Bouwman, A. F.

doi:10.1021/acs.est.9b03340

Cited by 114 publications

(48 citation statements)

References 29 publications

(64 reference statements)

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“…Riverine export and atmospheric deposition are responsible for most of the nitrogen inputs in most coastal areas (Figures 6 and S8). However, with the rapid increase in fish and shellfish production in marine waters particularly in China (Wang et al, 2020), mariculture is now locally as important as riverine export and atmospheric deposition (Figure S8).…”

Section: Discussionmentioning

confidence: 99%

“…However, our results indicate that much of the nitrogen load is from population centers close to the coast, and an initial policy focus on these regions may be more effective than on regions more upstream. Only 24% of the nitrogen in feed are retained by the cultured species and 66% are released from China's mariculture system to coastal waters (Wang et al, 2020), which means that the feed efficiency needs to be improved by adopting formulated feed (Cao et al, 2007; Wu, 1995). The policy of zero increase in fertilizer use is a first step toward reducing nitrogen losses from agriculture (Yu et al, 2019; Y. Zhang , 2015), but more stringent reductions may be needed in view of the legacy of the nitrogen that is temporarily stored in aquifers and that may add to future river export (Bouwman, Bierkens, Griffioen, et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

“…Aquaculture production data per country, species group, sea area, and type of environment are available in units of live weight for the period 1970–2010 from the FISHSTAT database (FAO, 2012). Aquaculture is spatially distributed within provinces or countries on the basis of water body type, population density, and temperature for inland and brackish aquaculture and coastal type, coastline length, and temperature as described by Wang et al (2020). The model scheme is in Figure S4.…”

Section: Methods and Data Usedmentioning

confidence: 99%

“…The nitrogen dynamics due to water exchange (e.g., ocean currents) and water‐sediment exchange in the seas were not considered. We used the Integrated Model to Assess the Global Environment–Global Nutrient Model (IMAGE‐GNM) (Beusen et al, 2015, 2016; Bouwman, Beusen, Glibert, et al, 2013; Wang et al, 2020) to estimate the spatial distribution of annual nitrogen inputs from river discharge, submarine fresh groundwater discharge and mariculture to the three Large Marine Ecosystems (LMEs, i.e., Yellow Sea/Bohai Sea, YS/BS; East China Sea, ECS; South China Sea, SCS, Figure 1) that border the coasts of China and several other countries for the period 1970–2010. Estimates of atmospheric nitrogen deposition to the seas were based on TM5‐FAst Scenario Screening Tool (TM5‐FASST) (Figure 2).…”

Section: Introductionmentioning

confidence: 99%

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Spatially Explicit Inventory of Sources of Nitrogen Inputs to the Yellow Sea, East China Sea, and South China Sea for the Period 1970–2010

et al. 2020

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Symptoms of eutrophication (including biodiversity loss, harmful algal blooms, and hypoxia) are an increasing problem in Chinese seas. Nutrient enrichment is primarily caused by accelerated human activities that cause nutrient pollution of the aquatic environment. In this study, the Integrated Model to Assess the Global Environment-Global Nutrient Model (IMAGE-GNM) was used to estimate nitrogen inputs from river discharge, submarine fresh groundwater discharge, and mariculture, and TM5-FAst Scenario Screening Tool (TM5-FASST) for atmospheric nitrogen deposition to the three Large Marine Ecosystems (LMEs, i.e., Yellow Sea/Bohai Sea, YS/BS; East China Sea, ECS; South China Sea, SCS) bordered by China and several other countries for the period 1970-2010. China's river nitrogen export was the largest nitrogen source in YS/BS and ECS. In SCS, however, China and other countries contributed equally and although decreasing, the proportion of natural sources remain considerable. The total nitrogen inputs to YS/BS (1.0 to 4.1 Tg year −1), ECS (1.3 to 5.5 Tg year −1), and SCS (2.1 to 5.8 Tg year −1) increased rapidly during 1970-2010. River export is dominated by agriculture; nitrogen inputs from atmospheric deposition and mariculture have been increasing rapidly in recent years. Considering only the coastal zone of the three LMEs, our results show that the total nitrogen inputs are strongly concentrated spatially in areas close to river mouths and those confined regions with mariculture production. To sustain the food production and economic growth in the coming decades, nitrogen inputs may increase further, depending on future eutrophication mitigation policies. Plain Language Summary Nitrogen is a limiting nutrient for plant production. Excessive nitrogen use in agriculture and discharge from wastewater is the primary causes of eutrophication in aquatic environments. Symptoms of eutrophication (including biodiversity loss, harmful algal blooms (HABs), and hypoxia) are an increasing problem in Chinese seas. Here we quantified the nitrogen inputs from river export, atmospheric deposition, submarine fresh groundwater discharge, and mariculture to the Yellow Sea/Bohai Sea (YS/BS), East China Sea (ECS), and South China Sea (SCS) bordered by China and other countries for the period 1970-2010. Nitrogen inputs increased rapidly, mainly due to increasing land-based sources (river export and atmospheric deposition), while nitrogen from mariculture started to increase recently. River export is dominated by agriculture with growing proportions of sewage and freshwater aquaculture. Nitrogen inputs were spatially concentrated and increased faster in Chinese coastal waters than in other countries. China's contribution to nitrogen pollution exceeded that of other countries in YS/BS and ECS, while China and other countries contributed equally in SCS. Nitrogen concentrations and HAB frequency in the seas seem to be correlated as both increased substantially since 1970s. Mitigation of nitrogen pollution is therefore urgent because human ac...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methods and Data Usedmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Spatially Explicit Inventory of Sources of Nitrogen Inputs to the Yellow Sea, East China Sea, and South China Sea for the Period 1970–2010

et al. 2020

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“…The contribution of the synthetic fertilizers was generally higher to the southern rivers (Yangtze, Pearl) than to the northern rivers (Yellow, Huai, Hai) [12] . Wastewaters [11] and aquaculture [36,37] are also important pollution sources but their contribution varies with scale (e.g., national, basin, sub-basin) [11,37] . At the national scale, livestock and crop production are dominant sources of nutrient pollution in water systems in 2012 [3,12] .…”

Section: Separation Of Crop and Animal Production Contributes To Watementioning

confidence: 99%

Green Agriculture and Blue Water in China: Reintegrating Crop and Livestock Production for Clean Water

Strokal¹,

Janssen²,

Chen

et al. 2021

Front. Agr. Sci. Eng.

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HIGHLIGHTS • AGD aims for a green environment, sustainable agriculture and clean water. • Presenting examples of the impact of agriculture on water quality. • Presenting examples of solutions for sustainable agriculture and improved water quality. • Integration of livestock and cropping systems is possible on a farm or among farms. • Providing recommendations for further development of sustainable agriculture.

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Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

Zhao

Liu

et al. 2021

Adv Funct Materials

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The demands for efficient and robust heterogeneous hydrogenation catalysts have triggered extensive research to optimize the structures of metal catalytic centers, but the potential of support construction for enhanced hydrogenation performance has been overlooked. This study introduces a hierarchically ordered porous poly(2,6-diaminopyridine) (PDAP) as a Pd nanoparticle support for hydrogenation removal of recalcitrant pollutants in water purification. The PDAP support acts as a sorbent and microreactor to enhance the proximity of targeted water pollutants and reactive hydrogen atom species, achieving unprecedently high water purification efficiency. The PDAP support also acts as a catalyst in mediating peroxide-activation for oxidative destruction of Pd poisons (e.g., reduced sulfur), achieving in situ regeneration of poisoned Pd catalysis centers. The high activity and in situ regenerativity achieved by rational construction of the support structure sheds light on a new approach for designing efficient and robust heterogeneous hydrogenation catalysts.

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Aquaculture Production is a Large, Spatially Concentrated Source of Nutrients in Chinese Freshwater and Coastal Seas

Cited by 114 publications

References 29 publications

Spatially Explicit Inventory of Sources of Nitrogen Inputs to the Yellow Sea, East China Sea, and South China Sea for the Period 1970–2010

Spatially Explicit Inventory of Sources of Nitrogen Inputs to the Yellow Sea, East China Sea, and South China Sea for the Period 1970–2010

Green Agriculture and Blue Water in China: Reintegrating Crop and Livestock Production for Clean Water

Constructing the Support as a Microreactor and Regenerator for Highly Active and In Situ Regenerative Hydrogenation Catalyst

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