Effects of anthropogenic nitrogen discharge on dissolved inorganic nitrogen transport in global rivers

Liu, Shuang; Xie, Zhenghui; Zeng, Yujing; Liu, Bin; Li, Ruichao; Wang, Yan; Wang, Longhuan; Qin, Peihua; Jia, Binghao; Xie, Jinbo

doi:10.1111/gcb.14570

Cited by 51 publications

(60 citation statements)

References 53 publications

(80 reference statements)

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“…Modeling studies exist to quantify past trends in river export of nutrients to seas in China (Liu et al, ; Liu et al, ; Qu & Kroeze, ; Strokal et al, ; UNEP, ). A few of these studies (Qu & Kroeze, ; Strokal et al, ; Strokal et al, ) explored future trends and focused on the impacts of socio‐economic change based on the old Millennium Ecosystem Assessment scenarios (Alcamo et al, ).…”

Section: Introductionmentioning

confidence: 99%

Global Change Can Make Coastal Eutrophication Control in China More Difficult

et al. 2020

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Fast socio-economic development in agriculture and urbanization resulted in increasing nutrient export by rivers, causing coastal eutrophication in China. In addition, climate change may affect hydrology, and as a result, nutrient flows from land to sea. This study aims at a better understanding of how future socio-economic and climatic changes may affect coastal eutrophication in China. We modeled river export of total dissolved nitrogen (TDN) and phosphorus (TDP) in 2050 for six scenarios combining socio-economic pathways (SSPs) and Representative Concentration Pathways (RCPs). We used the newly developed MARINA 2.0 (Model to Assess River Inputs of Nutrients to seAs) model. We found that global change can make coastal eutrophication control in China more difficult. In 2050 coastal waters may be considerably more polluted or considerably cleaner than today depending on the SSP-RCP scenarios. By 2050, river export of TDN and TDP is 52% and 56% higher than in 2012, respectively, in SSP3-RCP8.5 (assuming large challenges for sustainable socio-economic development, and severe climate change). In contrast, river export of nutrients could be 56% (TDN) and 85% (TDP) lower in 2050 than in 2012 in SSP1-RCP2.6 (assuming sustainable socio-economic development, and low climate change). Climate change alone may increase river export of nutrients considerably through hydrology: We calculate 24% higher river export of TDN and 16% higher TDP for the SSP2 scenario assuming severe climate change compared to the same scenario with low climate change (SSP2-RCP8.5 vs. SSP2-RCP2.6). Policies and relevant technologies combining improved nutrient management and climate mitigation may help to improve water quality in rivers and coastal waters of China.Plain Language Summary Fast socio-economic development has resulted in increasing nutrient export by rivers, causing coastal eutrophication in China. In addition, climate change may affect river discharge, and as a result, nutrient flows from land to sea. We explored how future socio-economic and climatic changes may affect coastal eutrophication in China. We found that in 2050 coastal waters may be considerably more polluted or considerably cleaner than today depending on the socio-economic development and climate change. By 2050, river export of total dissolved nitrogen (TDN) and phosphorus (TDP) is 52% and 56% higher than in 2012, respectively, in a scenario assuming large challenges for sustainable socio-economic development and severe climate change. In contrast, river export of nutrients could be 56% (TDN) and 85% (TDP) lower in 2050 than in 2012 in the scenario assuming sustainable socioeconomic development and low climate change. Climate change alone may increase river export of nutrients considerably: we calculate 24% higher river export of TDN and 16% higher TDP for a scenario assuming severe climate change compared to the same scenario with low climate change. Policies combining improved nutrient management and climate mitigation may help to improve water quality in rivers and c...

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Section: Introductionmentioning

confidence: 99%

Global Change Can Make Coastal Eutrophication Control in China More Difficult

et al. 2020

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“…However, a majority of the N applied to agricultural crops in this region is not harvested and thus subject to loss from the plant-soil system [3]. The unharvested N is associated with emissions of nitrous oxides [4], runoff and leaching of nitrate [5], and the degradation of aquatic and terrestrial ecosystems [6][7]. Therefore, the development of wheat cultivars that more efficiently take up and utilize applied N provides a means of promoting grower profitability and ensuring environmentally sustainable increases in wheat production.…”

Section: Introductionmentioning

confidence: 99%

Identification of quantitative trait loci associated with nitrogen use efficiency in winter wheat

et al. 2020

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Maintaining winter wheat (Triticum aestivum L.) productivity with more efficient nitrogen (N) management will enable growers to increase profitability and reduce the negative environmental impacts associated with nitrogen loss. Wheat breeders would therefore benefit greatly from the identification and application of genetic markers associated with nitrogen use efficiency (NUE). To investigate the genetics underlying N response, two bi-parental mapping populations were developed and grown in four site-seasons under low and high N rates. The populations were derived from a cross between previously identified high NUE parents (VA05W-151 and VA09W-52) and a shared common low NUE parent, 'Yorktown.' The Yorktown × VA05W-151 population was comprised of 136 recombinant inbred lines while the Yorktown × VA09W-52 population was comprised of 138 doubled haploids. Phenotypic data was collected on parental lines and their progeny for 11 N-related traits and genotypes were sequenced using a genotyping-by-sequencing platform to detect more than 3,100 high quality single nucleotide polymorphisms in each population. A total of 130 quantitative trait loci (QTL) were detected on 20 chromosomes, six of which were associated with NUE and N-related traits in multiple testing environments. Two of the six QTL for NUE were associated with known photoperiod (Ppd-D1 on chromosome 2D) and disease resistance (FHB-4A) genes, two were reported in previous investigations, and one QTL, QNue.151-1D, was novel. The NUE QTL on 1D, 6A, 7A, and 7D had LOD scores ranging from 2.63 to 8.33 and explained up to 18.1% of the phenotypic variation. The QTL identified in this study have potential for marker-assisted breeding for NUE traits in soft red winter wheat.

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“…To increase trust in our model results, we compared our results with other independent studies. We compared the total DIN inputs to rivers of the Yangtze (from Section 3.2 and Table 1) 23,40,41 and the total N inputs to crop production in the entire basin (Table 1). 11,12,15 Our results for N inputs to the rivers as DIN were comparable with results from other models ( Table 1).…”

Section: Model Uncertaintiesmentioning

confidence: 99%

Modeling the Contribution of Crops to Nitrogen Pollution in the Yangtze River

Chen

Strokal

Kroeze

et al. 2020

Environ. Sci. Technol.

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Agriculture contributes considerably to nitrogen (N) inputs to the world's rivers. In this study, we aim to improve our understanding of the contribution of different crops to N inputs to rivers. To this end, we developed a new model system by linking the MARINA 2.0 (Model to Assess River Input of Nutrient to seAs) and WOFOST (WOrld FOod STudy) models. We applied this linked model system to the Yangtze as an illustrative example. The N inputs to crops in the Yangtze River basin showed large spatial variability. Our results indicate that approximately 6,000 Gg of N entered all rivers of the Yangtze basin from crop production as dissolved inorganic N (DIN) in 2012. Half of this amount is from the production of single rice, wheat, and vegetables, where synthetic fertilizers were largely applied. In general, animal manure contributes 12% to total DIN inputs to rivers. Threequarters of manure-related DIN in rivers are from vegetable, fruit, and potato production. The contributions of crops to river pollution differ among sub-basins. For example, potato is an important source of DIN in rivers of some upstream sub-basins. Our results may help to prioritize the dominant crop sources for management to mitigate N pollution in the future.

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Effects of anthropogenic nitrogen discharge on dissolved inorganic nitrogen transport in global rivers

Cited by 51 publications

References 53 publications

Global Change Can Make Coastal Eutrophication Control in China More Difficult

Global Change Can Make Coastal Eutrophication Control in China More Difficult

Identification of quantitative trait loci associated with nitrogen use efficiency in winter wheat

Modeling the Contribution of Crops to Nitrogen Pollution in the Yangtze River

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