Spatial distributions of macronutrients, heavy metals and microplastics in surface sediments of the mainstem and lakes in the middle part of the Yellow River Basin

Xiajie Zhai , Lijuan Cui , Wei Li , Xinsheng Zhao , Chenxi Liu , Hua Ma , Mingshuo Xiong

Geoscience Frontiers ›› 2026, Vol. 17 ›› Issue (1) : 102214

PDF
Geoscience Frontiers ›› 2026, Vol. 17 ›› Issue (1) :102214 DOI: 10.1016/j.gsf.2025.102214
research-article
Spatial distributions of macronutrients, heavy metals and microplastics in surface sediments of the mainstem and lakes in the middle part of the Yellow River Basin
Author information +
History +
PDF

Abstract

The Yellow River provides an important foundation for the sustainable development of Chinese civilization. Compared with the upper part (dominated by the Tibetan Plateau) and the lower part (represented by the Yellow River Delta), the central part of the Yellow River Basin (encompassing most of the Loess Plateau) is the most arid and exhibits the most complex relationship between humans and nature. The Chinese government is continuously promoting the protection and management of the ecological environment in the central part of the Yellow River Basin, as it is related to the country’s food security and people’s health, biodiversity conservation and sustainable socio-economic development. However, the distribution patterns and evolution of key ecological elements in the region, which are important determinants of ecosystem productivity and health, have yet to be revealed. This study focused on three key ecological elements, namely, macronutrients (sediment organic carbon, SOC, total nitrogen, TN and total phosphorous, TP), heavy metals (Cu, Ni, Pb, Zn, Cr, Cd, Hg, and As) and microplastics, and aimed to systematically elucidate the change patterns of their concentrations and compositions in sediments from the mainstem of the Yellow River and neighboring typical lakes. The results revealed that the TN content was mostly greater than the SOC content in the sediments from the mainstem of the Yellow River. Moreover, the TN, SOC and heavy metal concentrations increased significantly as a result of agricultural cultivation. Among the six typical lakes, the highest concentrations of both macronutrients and heavy metals were observed in sediment samples from Mingcui Lake (MC; an urban wetland), followed by those in sediment samples from Wuliangsuhai Lake (WLS; surrounded by agricultural fields). Among the heavy metals, the concentrations of Zn and Cr were highest. The abundance of microplastics in the sediments from the mainstream of the Yellow River ranged from 233 to 3333 items kg-1, while the abundance of microplastics in lake sediments ranged from 967 to 1556 items kg-1. The other characteristics of microplastics were consistent, including the concentration of microplastic particles within the 0.2-2 mm range. The main colors of the sampled microplastics were blue, transparent, and gray-black. In addition, rayon accounted for the highest proportion among all polymer types, followed by PET and PE + PP. In general, the amount of the above three environmental elements is closely correlated with the intensity of human activities such as agriculture and urbanization. Stronger correlations were obtained between the concentrations of macronutrients and heavy metals. This study systematically reveals the change patterns of key ecological elements in the study area and advances the understanding of environmental changes, ecosystem evolution and sustainable development in the Yellow River Basin.

Keywords

Yellow River / Lakes / Macronutrients / Heavy metals / Sediments / Microplastics

Cite this article

Download citation ▾
Xiajie Zhai, Lijuan Cui, Wei Li, Xinsheng Zhao, Chenxi Liu, Hua Ma, Mingshuo Xiong. Spatial distributions of macronutrients, heavy metals and microplastics in surface sediments of the mainstem and lakes in the middle part of the Yellow River Basin. Geoscience Frontiers, 2026, 17(1): 102214 DOI:10.1016/j.gsf.2025.102214

登录浏览全文

4963

注册一个新账户 忘记密码

CRediT authorship contribution statement

Xiajie Zhai: Writing - review & editing, Writing - original draft, Visualization, Supervision, Investigation, Funding acquisition, Formal analysis, Data curation, Conceptualization. Lijuan Cui: Writing - review & editing, Supervision, Conceptualization. Wei Li: Investigation. Xinsheng Zhao: Software, Investigation. Chenxi Liu: Visualization, Software. Hua Ma: Investigation. Mingshuo Xiong: Investigation.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgements

This study was supported by National Nonprofit Institute Research Grant (No. CAFYBB2023ZA008-01).

References

Publishing order | Descend order by publishing year | Descend order by cited within
[1]

Albert, J.S., Carnaval, A.C., Flantua, S.G.A., Lohmann, L.G., Ribas, C.C., Riff, D., Carrillo, J.D., Fan, Y., Figueiredo, J.J.P., Guayasamin, J.M., Hoorn, C., de Melo, G.H., Nascimento, N., Quesada, C.A., Ulloa Ulloa, C., Val, P., Arieira, J., Encalada, A.C., Nobre, C.A., 2023. Human impacts outpace natural processes in the Amazon. Science 379 (6630), eabo5003.
[2]

Ashrafy, A., Liza, A.A., Islam, M.N., Billah, M.M., Arafat, S.T., Rahman, M.M., Rahman, S.M., 2023. Microplastics pollution: a brief review of its source and abundance in different aquatic ecosystems. J. Hazard. Mater. Adv. 9, 100215.
[3]

Battin, T.J., Lauerwald, R., Bernhardt, E.S., Bertuzzo, E., Gener, L.G., Hall Jr, R.O., Hotchkiss, E.R., Maavara, T., Pavelsky, T.M., Ran, L., Raymond, P., Rosentreter, J.A., Regnier, P., 2023. River ecosystem metabolism and carbon biogeochemistry in a changing world. Nature 613 (7944), 449-459.
[4]

Bergstrom, D.M., Wienecke, B.C., van den Hoff, J., Hughes, L., Lindenmayer, D.B., Ainsworth, T.D., Baker, C.M., Bland, L., Bowman, D.M.J.S., Brooks, S.T., Canadell, J.G., Constable, A.J., Dafforn, K.A., Depledge, M.H., Dickson, C.R., Duke, N.C., Helmstedt, K.J., Holz, A., Johnson, C.R., McGeoch, M.A., Melbourne-Thomas, J., Morgain, R., Nicholson, E., Prober, S.M., Raymond, B., Ritchie, E.G., Robinson, S.A., Ruthrof, K.X., Setterfield, S.A., Sgrò C.M., Stark, J.S., Travers, T., Trebilco, R., Ward, D.F.L., Wardle, G.M., Williams, K.J., Zylstra, P.J., Shaw, J.D., 2021. Combating ecosystem collapse from the tropics to the Antarctic. Global Change Biol. 27 (9), 1692-1703.
[5]

Best, J., 2018. Anthropogenic stresses on the world’s big rivers. Nat. Geosci. 12 (1), 7-21.
[6]

Brahney, J., Hallerud, M., Heim, E., Hahnenberger, M., Sukumaran, S., 2020. Plastic rain in protected areas of the United States. Science 368 (6496), 1257-1260.
[7]

Briffa, J., Sinagra, E., Blundell, R., 2020. Heavy metal pollution in the environment and their toxicological effects on humans. Heliyon 6 (9), e04691.
[8]

Brooks, A.L., Havas, V., 2025. Strengthening global plastic policy with systems analysis. Nat. Sustain. 8 (6), 714-723.
[9]

Corcoran, P.L., Belontz, S.L., Ryan, K., Walzak, M.J., 2020. Factors controlling the distribution of microplastic particles in benthic sediment of the Thames River, Canada. Environ. Sci. Technol. 54 (2), 818-825.
[10]

Cottom, J.W., Cook, E., Velis, C.A., 2024. A local-to-global emissions inventory of macroplastic pollution. Nature 633 (8028), 101-108.
[11]

De Falco, F., Cocca, M., Avella, M., Thompson, R.C., 2020. Microfiber release to water, via laundering, and to air, via everyday use: a comparison between polyester clothing with differing textile parameters. Environ. Sci. Technol. 54 (6), 3288-3296.
[12]

Devi, P.I., Manjula, M., Bhavani, R.V., 2022. Agrochemicals, environment, and human health. Annu. Rev. Environ. Resour. 47, 399-421.
[13]

Dimante-Deimantovica, I., Saarni, S., Barone, M., Buhhalko, N., Stivrins, N., Suhareva, N., Tylmann, W., Vianello, A., Vollertsen, J., 2024. Downward migrating microplastics in lake sediments are a tricky indicator for the onset of the Anthropocene. Sci. Adv. 10 (8), eadi8136.
[14]

Dittmar, S., Ruhl, A.S., Altmann, K., Jekel, M., 2024. Settling velocities of small microplastic fragments and fibers. Environ. Sci. Technol. 58 (14), 6359-6369.
[15]

Drummond, J.D., Schneidewind, U., Li, A., Hoellein, T.J., Krause, S., Packman, A.I., 2022. Microplastic accumulation in riverbed sediment via hyporheic exchange from headwaters to mainstems. Sci. Adv. 8 (2), eabi9305.
[16]

Gao, W., Huang, Z., Li, X., Ji, B., Li, N., Li, S., Liu, X., Zeng, Q., Sun, G., Zhao, D., 2024a. The spatial-temporal changes and driving factors of desertification in the Wuliangsuhai watershed based on remote sensing. Ecol. Indic. 169, 112851.
[17]

Gao, Y., Jia, J., Lu, Y., Sun, K., Wang, J., Wang, S., 2024b. Carbon transportation, transformation, and sedimentation processes at the land-river-estuary continuum. Fundam. Res. 4 (6), 1594-1602.
[18]

Hampton, S.E., Powers, S.M., Dugan, H.A., Knoll, L.B., McMeans, B.C., Meyer, M.F., O’Reilly, C.M., Ozersky, T., Sharma, S., Barrett, D.C., Chandra, S., Jansen, J., McClure, R.P., Rautio, M., Weyhenmeyer, G.A., Yang, X., 2024. Environmental and societal consequences of winter ice loss from lakes. Science 386 (6718), eadl3211.
[19]

Hauer, C., Leitner, P., Unfer, G., Pulg, U., Habersack, H., Graf, W., 2018. The role of sediment and sediment dynamics in the aquatic environment. In: Schmutz S., Sendzimir J. (Eds.),Riverine Ecosystem Management. Springer International Publishing, Cham., pp. 151-169.
[20]

Hou, D., Jia, X., Wang, L., McGrath, S.P., Zhu, Y.G., Hu, Q., Zhao, F.J., Bank, M.S., O’Connor, D., Nriagu, J., 2025. Global soil pollution by toxic metals threatens agriculture and human health. Science 388 (6744), 316-321.
[21]

Huang, W., Xia, X., 2024. Element cycling with micro(nano)plastics. Science 385 (6712), 933-935.
[22]

Hurley, R., Woodward, J., Rothwell, J.J., 2018. Microplastic contamination of river beds significantly reduced by catchment-wide flooding. Nat. Geosci. 11 (4), 251-257.
[23]

Islam, S.T., Rahman, S.H., Matin, M.A., Dey, A., Talukder, B., Sanyal, N., Asadujjaman, M., Akand, K., 2024. State of the world’s rivers. Annu. Rev. Environ. Resour. 49, 137-162.
[24]

Ji, P., Chen, J., Chen, R., Liu, J., Yu, C., Chen, F., 2024. Nitrogen and phosphorus trends in lake sediments of China may diverge. Nat. Commun. 15 (1), 2644.
[25]

Jones, E.R., Bierkens, M.F., van Puijenbroek, P.J., van Beek, L.R.P., Wanders, N., Sutanudjaja, E.H., van Vliet, M.T., 2023. Sub-Saharan Africa will increasingly become the dominant hotspot of surface water pollution. Nat. Water 1 (7), 602-613.
[26]

Larson, J.H., Bailey, S.W., Maki, R.P., Christensen, V.G., Stelzer, E.A., Smith, J.C., LeDuc, J.F., McWhorter, S., 2025. Possible influence of water level management on nutrient flux in nearshore sediments of Kabetogama Lake, Minnesota, USA. Ecosphere 16 (2), e70176.
[27]

Leibowitz, S.G., Hill, R.A., Creed, I.F., Compton, J.E., Golden, H.E., Weber, M.H., Rains, M.C., Jones Jr, C.E., Lee, E.H., Christensen, J.R., Bellmore, R.A., Lane, C.R., 2023. National hydrologic connectivity classification links wetlands with stream water quality. Nat. Water 1 (4), 370-380.
[28]

Lenaker, P.L., Corsi, S.R., Mason, S.A., 2021. Spatial distribution of microplastics in surficial benthic sediment of Lake Michigan and Lake Erie. Environ. Sci. Technol. 55 (1), 373-384.
[29]

Li, D., Lu, X., Overeem, I., Walling, D.E., Syvitski, J., Kettner, A.J., Bookhagen, B., Zhou, Y., Zhang, T., 2021. Exceptional increases in fluvial sediment fluxes in a warmer and wetter High Mountain Asia. Science 374 (6567), 599-603.
[30]

Li, Q., Han, Z., Su, G., Hou, M., Liu, X., Zhao, X., Hua, Y., Shi, B., Meng, J., Wang, M., 2023a. New insights into the distribution, potential source and risk of microplastics in Qinghai-Tibet Plateau. Environ. Int. 175, 107956.
[31]

Li, W., Qian, H., Xu, P., Zhang, Q., Chen, J., Hou, K., Ren, W., Qu, W., Chen, Y., 2022. Distribution characteristics, source identification and risk assessment of heavy metals in surface sediments of the Yellow River, China. Catena 216, 106376.
[32]

Li, Y., Zhang, Q., Baartman, J., van Wijnen, J., Beriot, N., Kroeze, C., Wang, M., Xu, W., Ma, L., Wang, K., Zhang, F., Strokal, M., 2023b. The plastic age: river pollution in China from crop production and urbanization. Environ. Sci. Technol. 57 (32), 12019-12032.
[33]

Lin, C., He, M., Zhou, Y., Guo, W., Yang, Z., 2008. Distribution and contamination assessment of heavy metals in sediment of the Second Songhua River, China. Environ. Monit. Assess. 137 (1), 329-342.
[34]

Lin, Q., Zhang, K., Giguet-Covex, C., Arnaud, F., McGowan, S., Gielly, L., Capo, E., Huang, S., Ficetola, G.F., Shen, J., Dearing, J.A., Meadows, M.E., 2024. Transient social-ecological dynamics reveal signals of decoupling in a highly disturbed Anthropocene landscape. Proc. Natl. Acad. Sci.U.S.A. 121 (17), e2321303121.
[35]

Liu, K., Wu, Q., Wang, S., Ouyang, D., Li, Z., Ding, D., Li, G., Tang, Y., Xiang, L., Han, D., Wen, M., Liu, T., Duan, L., Tian, H., Hao, J., 2021a. Highly resolved inventory of mercury release to water from anthropogenic sources in China. Environ. Sci. Technol. 55 (20), 13860-13868.
[36]

Liu, P., Zhou, H., Chun, X., Wan, Z., Liu, T., Sun, B., Wang, J., Zhang, W., 2022. Characteristics of fine carbonaceous aerosols in Wuhai, a resource-based city in Northern China: insights from energy efficiency and population density. Environ. Pollut. 292 (Pt A), 118368.
[37]

Liu, R.P., Li, Z.Z., Liu, F., Dong, Y., Jiao, J.G., Sun, P.P., Rm, E.W., 2021b. Microplastic pollution in Yellow River, China: current status and research progress of biotoxicological effects. China Geol. 4 (4), 585-592.
[38]

Liu, Y., Song, H., An, Z., Sun, C., Trouet, V., Cai, Q., Liu, R., Leavitt, S.W., Song, Y., Li, Q., Fang, C., 2020. Recent anthropogenic curtailing of Yellow River runoff and sediment load is unprecedented over the past 500 y. Proc. Natl. Acad. Sci. U S A. 117 (31), 18251-18257.
[39]

Kanter, D.R., Chodos, O., Nordland, O., Rutigliano, M., Winiwarter, W., 2020. Gaps and opportunities in nitrogen pollution policies around the world. Nat. Sustain. 3 (11), 956-963.
[40]

Kuang, W., Liu, J., Tian, H., Shi, H., Dong, J., Song, C., Li, X., Du, G., Hou, Y., Lu, D., Chi, W., 2022. Cropland redistribution to marginal lands undermines environmental sustainability. Natl. Sci. Rev. 9 (1), 66-78.
[41]

Kumar, V., Pandita, S., Setia, R., 2022. A meta-analysis of potential ecological risk evaluation of heavy metals in sediments and soils. Gondwana Res. 103, 487-501.
[42]

Miranda, L.S., Wijesiri, B., Ayoko, G.A., Egodawatta, P., Goonetilleke, A., 2021. Water-sediment interactions and mobility of heavy metals in aquatic environments. Water Res. 202, 117386.
[43]

Messager, M.L., Lehner, B., Cockburn, C., Lamouroux, N., Pella, H., Snelder, T., Tockner, K., Trautmann, T., Watt, C., Datry, T., 2021. Global prevalence of non-perennial rivers and streams. Nature 594 (7863), 391-397.
[44]

Naeem, M., Zhang, Y., Tian, X., Miao, P., Li, C., Xu, Z., Wang, L., Mumtaz, F., Tang, Z., He, S., 2025. Assessing and predicting Bojiang lake area and LULC changes from 2000 to 2045. J. Hydrol.: Reg. Stud. 58, 102216.
[45]

Naidu, R., Biswas, B., Willett, I.R., Cribb, J., Kumar Singh, B., Paul Nathanail, C., Coulon, F., Semple, K.T., Jones, K.C., Barclay, A., Aitken, R.J., 2021. Chemical pollution: a growing peril and potential catastrophic risk to humanity. Environ. Int. 156, 106616.
[46]

Naylor, L.A., Dungait, J.A., Zheng, Y., Buckerfield, S., Green, S.M., Oliver, D.M., Liu, H., Peng, J., Tu, C., Zhang, G.L., Zhang, X., 2023. Achieving sustainable Earth futures in the Anthropocene by including local communities in critical zone science. Earth’s Future 11 (9), e2022EF003448.
[47]

Napper, I.E., Thompson, R.C., 2023. Plastics and the environment. Annu. Rev. Environ. Resour. 48, 55-79.
[48]

Nizzetto, L., Bussi, G., Futter, M.N., Butterfield, D., Whitehead, P.G., 2016. A theoretical assessment of microplastic transport in river catchments and their retention by soils and river sediments. Environ. Sci. Process. Impacts 18 (8), 1050-1059.
[49]

Okeke, E.S., Okoye, C.O., Atakpa, E.O., Ita, R.E., Nyaruaba, R., Mgbechidinma, C.L., Akan, O.D., 2022. Microplastics in agroecosystems-impacts on ecosystem functions and food chain. Resour. Conserv. Recy. 177, 105961.
[50]

Pandey, N., Tiwari, A., 2021. Human health risk assessment of heavy metals in different soils and sediments. In: Kumar V., Sharma A., Cerdà A. (Eds.),Heavy Metals in the Environment. Elsevier, pp. 143-163.
[51]

Palmer, M., Ruhi, A., 2019. Linkages between flow regime, biota, and ecosystem processes: implications for river restoration. Science 365 (6459), eaaw2087.
[52]

Peñuelas, J., Sardans, J., 2022. The global nitrogen-phosphorus imbalance. Science 375 (6578), 266-267.
[53]

Pietz, D.A., 2015. The Yellow River:The Problem of Water in Modern China. Harvard University Press, Cambridge, pp. 10-27.
[54]

Rohais, S., Armitage, J.J., Romero-Sarmiento, M., Pierson, J., Teles, V., Bauer, D., Cassar, C., Sebag, D., Klopffer, M.H., Pelerin, M., 2024. A source-to-sink perspective of an anthropogenic marker: a first assessment of microplastics concentration, pathways, and accumulation across the environment. Earth Sci. Rev. 254, 104822.
[55]

Salgado, J., Jaramillo-Monroy, C., Link, A., Lopera-Congote, L., Vélez, M.I., González-Arango, C., Yang, H., Panizzo, V.N., McGowan, S., 2024. Riverine connectivity modulates elemental fluxes through a 200-year period of intensive anthropic change in the Magdalena River floodplains, Colombia. Water Res. 268 (Pt A), 122633.
[56]

Sarkar, D.J., Das Sarkar, S., Das, B.K., Sahoo, B.K., Das, A., Nag, S.K., Manna, R.K., Behera, B.K., Samanta, S., 2021. Occurrence, fate and removal of microplastics as heavy metal vector in natural wastewater treatment wetland system. Water Res. 192, 116853.
[57]

Schindler, D.W., Carpenter, S.R., Chapra, S.C., Hecky, R.E., Orihel, D.M., 2016. Reducing phosphorus to curb Lake eutrophication is a success. Environ. Sci. Technol. 50 (17), 8923-8929.
[58]

Shi, X., Ma, Y., Ma, Y., Lin, W., Zhu, L., Li, D., Tong, Y., Lin, Y., 2025. A comprehensive modeling of microplastic emission from wastewater treatment plants to the sea via rivers in China. Environ. Sci. Technol. 59 (7), 3679-3690.
[59]

Sun, J., Zhang, D., Peng, S., Yang, X., Hua, Q., Wang, W., Wang, Y., Lin, X., 2024a. Occurrence and human exposure risk of antibiotic resistance genes in tillage soils of dryland regions: a case study of northern Ningxia Plain, China. J. Hazard. Mater. 480, 135790.
[60]

Sun, M., Zhang, L., Yang, R., Li, X., Zhao, J., Liu, Q., 2024b. Water resource dynamics and protection strategies for inland lakes: a case study of Hongjiannao Lake. J. Environ. Manage. 355, 120462.
[61]

Syvitski, J., Ángel, J.R., Saito, Y., Overeem, I., Vörösmarty, C.J., Wang, H., Olago, D., 2022. Earth’s sediment cycle during the Anthropocene. Nat. Rev. Earth Environ. 3 (3), 179-196.
[62]

Thompson, R.C., Courtene-Jones, W., Boucher, J., Pahl, S., Raubenheimer, K., Koelmans, A.A., 2024. Twenty years of microplastic pollution research-what have we learned? Science 386 (6720), eadl2746.
[63]

Tian, S., Xu, M., Jiang, E., Wang, G., Hu, H., Liu, X., 2019. Temporal variations of runoff and sediment load in the upper Yellow River, China. J. Hydrol. 568, 46-56.
[64]

Tiegs, S. D., Capps, K. A., Costello, D. M., Schmidt, J. P., Patrick, C. J., Follstad Shah, J. J., LeRoy, C. J.,CELLDEX Consortium, 2024. Human activities shape global patterns of decomposition rates in rivers. Science. 384(6701), 1191-1195.
[65]

Villarrubia-Gómez, P., Carney Almroth, B.M., Eriksen, M., Ryberg, M., Cornell, S.E., 2024. Plastics pollution exacerbates the impacts of all planetary boundaries. One Earth 7 (12), 2119-2138.
[66]

Waldschläger, K., Brückner, M.Z., Almroth, B.C., Hackney, C.R., Adyel, T.M., Alimi, O.S., Belontz, S.L., Cowger, W., Doyle, D., Gray, A., Kane, I., 2022. Learning from natural sediments to tackle microplastics challenges: a multidisciplinary perspective. Earth Sci. Rev. 228, 104021.
[67]

Wang, F., Xiang, L., Sze-Yin Leung, K., Elsner, M., Zhang, Y., Guo, Y., Pan, B., Sun, H., An, T., Ying, G., Brooks, B.W., 2024a. Emerging contaminants: a one health perspective. Innovation 5 (4), 100612.
[68]

Wang, J., Shi, B., Zhao, E., Yuan, Q., Chen, X., 2022. The long-term spatial and temporal variations of sediment loads and their causes of the Yellow River Basin. Catena 209, 105850.
[69]

Wang, J., Bouwman, A.F., Vilmin, L., Beusen, A.H., van Hoek, W.J., Liu, X., Middelburg, J.J., 2024b. Global inland-water nitrogen cycling has accelerated in the Anthropocene. Nat. Water 2 (8), 729-740.
[70]

Wang, S., Fu, B., Piao, S., Y., Ciais, P., Feng, X., Wang, Y., 2016. Reduced sediment transport in the Yellow River due to anthropogenic changes. Nat. Geosci. 9 (1), 38-41.
[71]

Wang, S.Y., Liu, J.S., Ma, T.B., 2010. Dynamics and changes in spatial patterns of land use in Yellow River basin, China. Land Use Pol. 27 (2), 313-323.
[72]

Wang, Y., Ouyang, W., Wang, A., Liu, L., Lin, C., He, M., 2021. Synergetic loss of heavy metal and phosphorus: evidence from geochemical fraction and estuary sedimentation. J. Hazard. Mater. 416, 125710.
[73]

Woodward, J., Li, J., Rothwell, J., Hurley, R., 2021. Acute riverine microplastic contamination due to avoidable releases of untreated wastewater. Nat. Sustain. 4 (9), 793-802.
[74]

Wu, Y., Xi, X., Tang, X., Luo, D., Gu, B., Lam, S.K., Vitousek, P.M., Chen, D., 2018. Policy distortions, farm size, and the overuse of agricultural chemicals in China. Proc. Natl. Acad. Sci. U.S.A. 115 (27), 7010-7015.
[75]

Xiao, T., Ran, F., Li, Z., Wang, S., Nie, X., Liu, Y., Yang, C., Tan, M., Feng, S., 2023. Sediment organic carbon dynamics response to land use change in diverse watershed anthropogenic activities. Environ. Int. 172, 107788.
[76]

Xie, F., Yu, M., Yuan, Q., Meng, Y., Qie, Y., Shang, Z., Luan, F., Zhang, D., 2022. Spatial distribution, pollution assessment, and source identification of heavy metals in the Yellow River. J. Hazard. Mater. 436, 129309.
[77]

Xu, M., Wang, G., Wang, Z., Hu, H., Kumar Singh, D., Tian, S., 2022. Temporal and spatial hydrological variations of the Yellow River in the past 60 years. J. Hydrol. 609, 127750.
[78]

Yang, Y., Tilman, D., Jin, Z., Smith, P., Barrett, C.B., Zhu, Y.G., Burney, J., D’Odorico, P., Fantke, P., Fargione, J., Finlay, J.C., Rulli, M.C., Sloat, L., Jan van Groenigen, K., West, P.C., Ziska, L., Michalak, A.M., Team, C-A., Lobell, D.B., 2024. Climate change exacerbates the environmental impacts of agriculture. Science 385 (6713), eadn3747.
[79]

Yu, Q., Yue, D., Wang, Y., Kai, S., Fang, M., Ma, H., Zhang, Q., 2018. Optimization of ecological node layout and stability analysis of ecological network in desert oasis: a typical case study of ecological fragile zone located at Deng Kou County (Inner Mongolia). Ecol. Indic. 84 (1), 304-318.
[80]

Yu, S.Y., Li, W.J., Zhou, L., Yu, X., Zhang, Q., Shen, Z., 2023. Human disturbances dominated the unprecedentedly high frequency of Yellow River flood over the last millennium. Sci. Adv. 9 (8), eadf8576.
[81]

Zamora-Ledezma, C., Negrete-Bolagay, D., Figueroa, F., Zamora-Ledezma, E., Ni, M., Alexis, F., Guerrero, V.H., 2021. Heavy metal water pollution: a fresh look about hazards, novel and conventional remediation methods. Environ. Technol. Innovation 22, 101504.
[82]

Zhang, Z., Yang, C., Qiao, Q., Li, X., Wang, F., Li, C., 2023. Application of improved particle swarm optimization SVM in water quality evaluation of Ming Cui Lake. Sustainability 15 (12), 9835.
[83]

Zhou, W., Yu, W., Qian, Y., Han, L., Pickett, S.T.A., Wang, J., Li, W., Ouyang, Z., 2022. Beyond city expansion: multi-scale environmental impacts of urban megaregion formation in China. Natl. Sci. Rev. 9 (1), nwab107.
PDF

4

Accesses

0

Citation

Detail
Sections
Recommended

/