Management of nutrient export from diffuse sources in watersheds for environmental protection under uncertainty

Q. Rong; M. Su; W. Yue; Y. Cai

doi:10.2489/jswc.2022.00192

References

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Keywords

[1] ↵
Cai, Y.,
Q. Rong,
Z. Yang,
W. Yue, and
Q. Tan
. 2018. An export coefficient based inexact fuzzy bi-level multi-objective programming model for the management of agricultural nonpoint source pollution under uncertainty. Journal of Hydrology 557:713–725.
OpenUrl

[2] Cai, Y.,

[3] Q. Rong,

[4] Z. Yang,

[5] W. Yue, and

[6] Q. Tan

[7] ↵
Chen, S.,
J. Xu,
Q. Li,
X. Tan, and
X. Nong
. 2019. A copula-based interval-bistochastic programming method for regional water allocation under uncertainty. Agricultural Water Management 217:154–164.
OpenUrl

[8] Chen, S.,

[9] J. Xu,

[10] Q. Li,

[11] X. Tan, and

[12] X. Nong

[13] ↵
Dai, C.,
Y.P. Cai,
W. Ren,
Y.F. Xie, and
H.C. Guo
. 2016. Identification of optimal placements of best management practices through an interval-fuzzy possibilistic programming model. Agricultural Water Management 165:108–121.
OpenUrl

[14] Dai, C.,

[15] Y.P. Cai,

[16] W. Ren,

[17] Y.F. Xie, and

[18] H.C. Guo

[19] ↵
Dougill, A.J.,
A.L. Heathwaite, and
D.S.G. Thomas
. 2015. Soil water movement and nutrient cycling in semiarid rangeland: Vegetation change and system resilience. Hydrological Processes 12:443–459.
OpenUrl

[20] Dougill, A.J.,

[21] A.L. Heathwaite, and

[22] D.S.G. Thomas

[23] ↵
Feier, W.,
S. Zuolei,
Z. Siyuan,
Y. Jie, and
L. Xinqiang
. 2018. An integrated approach to identify critical source areas of agricultural nonpoint-source pollution at the watershed scale. Journal of Environmental Quality 47:922.
OpenUrl

[24] Feier, W.,

[25] S. Zuolei,

[26] Z. Siyuan,

[27] Y. Jie, and

[28] L. Xinqiang

[29] ↵
Gong, Y.,
Z. Shen,
Q. Hong,
R. Liu, and
Q. Liao
. 2011. Parameter uncertainty analysis in watershed total phosphorus modeling using the GLUE methodology. Agriculture Ecosystems & Environment 142:246–255.
OpenUrl

[30] Gong, Y.,

[31] Z. Shen,

[32] Q. Hong,

[33] R. Liu, and

[34] Q. Liao

[35] ↵
Gui, Z.,
M. Li, and
P. Guo
. 2017. Simulation-based inexact fuzzy semi-infinite programming method for agricultural cultivated area planning in the Shiyang River basin. Journal of Irrigation & Drainage Engineering 143:05016011.1–05016011.14.
OpenUrl

[36] Gui, Z.,

[37] M. Li, and

[38] P. Guo

[39] ↵
He, S.,
Y. Hao,
J. Wu, and
J. Lu
. 2020. Estimation of baseflow nitrate loads by a recursive tracing source algorithm in a rainy agricultural watershed. Hydrological Processes 34:441–454.
OpenUrl

[40] He, S.,

[41] Y. Hao,

[42] J. Wu, and

[43] J. Lu

[44] ↵
Huang, G.H.,
B.W. Baetz, and
G.G. Patry
. 1995. Grey integer programming: An application to waste management planning under uncertainty. European Journal of Operational Research 83:594–620.
OpenUrl CrossRef Web of Science

[45] Huang, G.H.,

[46] B.W. Baetz, and

[47] G.G. Patry

[48] ↵
Huang, Y.L.,
G.H. Huang,
D.F. Liu,
H. Zhu, and
W. Sun
. 2012. Simulation-based inexact chance-constrained nonlinear programming for eutrophication management in the Xiangxi Bay of Three Gorges Reservoir. Journal of Environmental Management 108:54–65.
OpenUrl PubMed

[49] Huang, Y.L.,

[50] G.H. Huang,

[51] D.F. Liu,

[52] H. Zhu, and

[53] W. Sun

[54] ↵
Ji, Y.,
G.H. Huang, and
W. Sun
. 2014. Inexact left-hand-side chance-constrained programming for nonpoint-source water quality management. Water Air and Soil Pollution 225:14.
OpenUrl

[55] Ji, Y.,

[56] G.H. Huang, and

[57] W. Sun

[58] ↵
Jiang, K.,
Z. Li,
C. Luo,
M. Wu,
L. Chao,
Q. Zhou, and
H. Zhao
. 2019. The reduction effects of riparian reforestation on runoff and nutrient export based on AnnAGNPS model in a small typical watershed, China. Environmental Science and Pollution Research 26:5934–5943.
OpenUrl

[59] Jiang, K.,

[60] Z. Li,

[61] C. Luo,

[62] M. Wu,

[63] L. Chao,

[64] Q. Zhou, and

[65] H. Zhao

[66] ↵
Karki, R.,
M.L.M. Tagert,
J.O. Paz, and
R.L. Bingner
. 2017. Application of AnnAGNPS to model an agricultural watershed in East-Central Mississippi for the evaluation of an on-farm water storage (OFWS) system. Agricultural Water Management 192:103–114.
OpenUrl

[67] Karki, R.,

[68] M.L.M. Tagert,

[69] J.O. Paz, and

[70] R.L. Bingner

[71] ↵
Kemp, J.,
D. Lotter,
A. Meyer,
A. Kleinert,
M. Pérez-Fernández, and
A. Valentine
. 2018. Variation in rhizosphere nutrient cycling affects the source of nitrogen acquisition in wild and cultivated Aspalathus linearis (N.L.Burm.) R.Dahlgren plants. Applied Soil Ecology 130:26–33.
OpenUrl

[72] Kemp, J.,

[73] D. Lotter,

[74] A. Meyer,

[75] A. Kleinert,

[76] M. Pérez-Fernández, and

[77] A. Valentine

[78] ↵
Kumar, S.,
P.S. Bhavya,
R. Ramesh,
G.V.M. Gupta,
F. Chiriboga,
A. Singh,
I. Karunasagar,
A. Rai,
A. Rehnstam-Holm,
L. Edler, and
A. Godhe
. 2018. Nitrogen uptake potential under different temperature-salinity conditions: Implications for nitrogen cycling under climate change scenarios. Marine Environmental Research 141:196–204.
OpenUrl

[79] Kumar, S.,

[80] P.S. Bhavya,

[81] R. Ramesh,

[82] G.V.M. Gupta,

[83] F. Chiriboga,

[84] A. Singh,

[85] I. Karunasagar,

[86] A. Rai,

[87] A. Rehnstam-Holm,

[88] L. Edler, and

[89] A. Godhe

[90] ↵
Li, Y.P., and
G.H. Huang
. 2009. Two-stage planning for sustainable water-quality management under uncertainty. Journal of Environmental Management 90:2402–2413.
OpenUrl PubMed

[91] Li, Y.P., and

[92] G.H. Huang

[93] ↵
Liu, T.T.,
R.J.F. Bruins, and
M.T. Heberling
. 2018. Factors influencing farmers’ adoption of best management practices: A review and synthesis. Sustainability 10:26.
OpenUrl

[94] Liu, T.T.,

[95] R.J.F. Bruins, and

[96] M.T. Heberling

[97] ↵
Liu, Y.,
B.A. Engel,
D.C. Flanagan,
M.W. Gitau,
S.K. Mcmillan, and
I. Chaubey
. 2017. A review on effectiveness of best management practices in improving hydrology and water quality: Needs and opportunities. Science of the Total Environment 601–602:580–593.
OpenUrl

[98] Liu, Y.,

[99] B.A. Engel,

[100] D.C. Flanagan,

[101] M.W. Gitau,

[102] S.K. Mcmillan, and

[103] I. Chaubey

[104] ↵
Liu, J.,
X.L. Liu,
Y. Wang,
Y. Li,
Y.X. Jiang,
M.H. Wang, and
J. Wu
. 2020. Landscape pattern at the class level regulates the stream water nitrogen and phosphorus levels in a Chinese subtropical agricultural catchment. Agriculture Ecosystems & Environment 295:8.
OpenUrl

[105] Liu, J.,

[106] X.L. Liu,

[107] Y. Wang,

[108] Y. Li,

[109] Y.X. Jiang,

[110] M.H. Wang, and

[111] J. Wu

[112] ↵
Liu, Y.,
H. Long,
T. Li, and
S. Tu
. 2015a. Land use transitions and their effects on water environment in Huang-Huai-Hai Plain, China. Land Use Policy 47:293–301.
OpenUrl

[113] Liu, Y.,

[114] H. Long,

[115] T. Li, and

[116] S. Tu

[117] ↵
Liu, J.,
L. Zhang,
Y. Zhang, and
H. Deng H
. 2015b. Trade-off between water pollution prevention, agriculture profit, and farmer practice—An optimization methodology for discussion on land-use adjustment in China. Environmental Monitoring & Assessment 187:4104.
OpenUrl

[118] Liu, J.,

[119] L. Zhang,

[120] Y. Zhang, and

[121] H. Deng H

[122] ↵
Lu, H.,
P. Du,
Y. Chen, and
L. He
. 2016. A credibility-based chance-constrained optimization model for integrated agricultural and water resources management: A case study in South Central China. Journal of Hydrology 537:408–418.
OpenUrl

[123] Lu, H.,

[124] P. Du,

[125] Y. Chen, and

[126] L. He

[127] ↵
Luo, B.,
J.B. Li,
G.H. Huang, and
H.L. Li
. 2006. A simulation-based interval two-stage stochastic model for agricultural nonpoint source pollution control through land retirement. Science of the Total Environment 361:38–56.
OpenUrl PubMed

[128] Luo, B.,

[129] J.B. Li,

[130] G.H. Huang, and

[131] H.L. Li

[132] ↵
Mayorga, E.,
S.P. Seitzinger,
J.A. Harrison,
E. Dumont,
A.H.W. Beusen,
A.F. Bouwman,
B.M. Fekete,
C. Kroeze, and
G. Van Drecht
. 2010. Global Nutrient Export from WaterSheds 2 (NEWS 2): Model development and implementation. Environmental Modelling & Software 25:837–853.
OpenUrl

[133] Mayorga, E.,

[134] S.P. Seitzinger,

[135] J.A. Harrison,

[136] E. Dumont,

[137] A.H.W. Beusen,

[138] A.F. Bouwman,

[139] B.M. Fekete,

[140] C. Kroeze, and

[141] G. Van Drecht

[142] ↵
Qin, C.Z.,
H.R. Gao,
L.J. Zhu,
A.X. Zhu,
J.Z. Liu, and
H. Wu H
. 2018. Spatial optimization of watershed best management practices based on slope position units. Journal of Soil and Water Conservation 73(5):504–517. https://doi.org/10.2489/jswc.73.5.504.
OpenUrl Abstract/FREE Full Text

[143] Qin, C.Z.,

[144] H.R. Gao,

[145] L.J. Zhu,

[146] A.X. Zhu,

[147] J.Z. Liu, and

[148] H. Wu H

[149] ↵
Rong, Q.,
Y. Cai,
M. Su,
W. Yue,
Z. Yang, and
Z. Dang
. 2019. A simulation-based bi-level multi-objective programming model for watershed water quality management under interval and stochastic uncertainties. Journal of Environmental Management 245:418–431.
OpenUrl

[150] Rong, Q.,

[151] Y. Cai,

[152] M. Su,

[153] W. Yue,

[154] Z. Yang, and

[155] Z. Dang

[156] ↵
Roostaee, M., and
Z. Deng
. 2019. HSPF-based watershed-scale water quality modeling and uncertainty analysis. Environmental Science & Pollution Research 26:8971–8991.
OpenUrl

[157] Roostaee, M., and

[158] Z. Deng

[159] ↵
Rudnick, D.R.,
S. Irmak,
K. Djaman, and
V. Sharma
. 2017. Impact of irrigation and nitrogen fertilizer rate on soil water trends and maize evapotranspiration during the vegetative and reproductive periods. Agricultural Water Management 191:77–84.
OpenUrl

[160] Rudnick, D.R.,

[161] S. Irmak,

[162] K. Djaman, and

[163] V. Sharma

[164] ↵
Strokal, M., and
C. Kroeze
. 2013. Nitrogen and phosphorus inputs to the Black Sea in 1970–2050. Regional Environmental Change 13:179–192.
OpenUrl

[165] Strokal, M., and

[166] C. Kroeze

[167] ↵
Strokal, M.,
C. Kroeze,
L. Li,
S. Luan,
H. Wang,
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