Assessing non-point source pollution models: a review

• Autorzy: Adu J.T. , Kumarasamy M.V.
• Języki publikacji: EN

Abstrakty

EN

Although access to clean and potable water is a requirement for healthy living, the constant release of non-point source pollutants into water bodies has resulted in water quality degradation. In a bid to curb this situation, water quality models are used as a tool. This study reviews 10 non-point source models, namely: AGNPS, ANSWERS, CREAMS, SWRRB, HSPF, SWAT, EPD RIV1, DMA, CMBA, and MA, giving consideration to their nature, components, area of use, strengths, and limitations. Our review indicated that hydrological processes and mechanisms involved in the movement of non-point source pollutants have not been completely developed in these models. However, HSPF and EPD RIV1 models (which have in-stream process components) are limited due to limitations in their operations and computational difficulties. Further research would seek to develop a non-point source pollutant model that would not only adequately and effectively simulate non-point source pollutants in water bodies, but would also be easy to assess, user-friendly, and time-efficient.

• Wydawca: -
• Czasopismo: Polish Journal of Environmental Studies
• Rocznik: 2018
• Tom: 27
• Numer: 5
• Opis fizyczny: p.1913-1922,ref.

Twórcy

autor

Adu J.T.

• Civil Engineering Programme, School of Engineering, University of KwaZulu-Natal, Durban, South Africa

autor

Kumarasamy M.V.

• Civil Engineering Programme, School of Engineering, University of KwaZulu-Natal, Durban, South Africa

Bibliografia

• 1. KUMARASAMY M. Deoxygenation and reaeration coupled hybrid mixing cells based pollutant transport model to assess water quality status of a river. International journal of environmental research, 9, 341, 2015.
• 2. U.S. EPA. National management measures for the control of non-point pollution from agriculture, EPA-841-B-03-004, US Environmental Protection Agency, Office of Water, Washington, DC, 2003.
• 3. LI Q.K., LI H.E. The preliminary frame of non point source pollution study in the Yellow River watershed. Yellow River, 32(12), 131, 2010.
• 4. FU C., KANG W.Y. Research on spatial characteristics of TN & TP of agricultural non-point source pollution in the surrounding area of the Poyang lake. Resour Environ Yangtze Basin, 21 (7), 864, 2012.
• 5. ONGLEY E.D., ZHANG X., YU T. Current status of agricultural and rural non-point source Pollution assessment in China. Environmental Pollution, 158, 1159, 2010.
• 6. COLLICK A.S., FUKA D.R., KLEINMAN P.J.A., BUDA A.R., WELD J.L., WHITE M.J., VEITH T.L., BRYANT R.B., BOLSTER C.H., EASTON Z.M. Predicting phosphorus dynamics in complex terrains using a variable source area hydrology model. Hydrol. Process., 29 (4), 588, 2015.
• 7. POUDEL D.D. Surface water quality monitoring of an agricultural watershed for nonpoint source pollution control. Journal of Soil and Water Conservation, 71 (4), 310, 2016.
• 8. LOAGUE K., CORWIN D.L. Point and nonpoint source pollution. Encyclopedia of hydrological sciences, 2005.
• 9. JHA R., OJHA C.S.P., BHATIA K.K.S. Non-point source pollution estimation using a modified approach. Hydrological processes, 21, 1098, 2007.
• 10. DONG Y., LIU Y., CHEN J. Will urban expansion lead to an increase in future water pollution loads? – a preliminary investigation of the Haihe River Basin in northeastern China. Environmental Science and Pollution Research, 21 (11), 7024, 2014.
• 11. WANG A., TANG L., YANG D. Spatial and temporal variability of nitrogen load from catchment and retention along a river network: a case study in the upper Xin’anjiang catchment of China. Hydrology Research, 47 (4), 869, 2016.
• 12. ZHANG H., HUANG G. H. Assessment of non-point source pollution using a spatial multicriteria analysis approach. Ecological Modelling, 222(2), 313, 2010.
• 13. SHEN Z., LIAO Q., HONG Q., GONG Y. An overview of research on agricultural non-point source pollution modelling in China. Separation and Purification Technology, 84, 104, 2012.
• 14. GAO X.P., LI G.N., LI G.R., ZHANG C. Modeling the effects of point and non-point source pollution on a diversion channel from Yellow River to an artificial lake in China. Water Science & Technology, 71, 1806, 2015.
• 15. Li J.K. Research on non-point source pollution load quantification for watershed-taking the Weihe river basin as an example. Doctoral dissertation, Xian: Xi’an University of Technology, 2009.
• 16. WU L., LONG T., LIU X., GUO J. S. Impacts of climate and land-use changes on the migration of non-point source TN and phosphorus during rainfall-runoff in the Jialing River Watershed, China. J. Hydrol. 475, 26, 2012.
• 17. SHEN Z., QIU J., HONG Q., CHEN L. Simulation of spatial and temporal distributions of non-point source pollution load in the Three Gorges Reservoir Region. Science of the Total Environment, 493, 138, 2014.
• 18. HAN L., HUO F., SUN J. Method for calculating non-point source pollution distribution in plain rivers Water Science and Engineering, 4 (1), 83, 2011.
• 19. MA X., LI Y., ZHANG M., ZHENG F.Z., DU S. Assessment and analysis of non-point source nitrogen and phosphorus loads in the Three Gorges Reservoir Area of Hubei Province, China. Science of the Total Environment, 412, 154, 2011.
• 20. AMAYA F.L., GONZALES T.A., HERNANDEZ E.C., LUZANO E.V., MERCADO N.P. Estimating Point and Non-Point Sources of Pollution in Biñan River Basin, the Philippines. APCBEE Procedia, 1, 233, 2012.
• 21. LEE S.C., PARK I.H., KIM B.S., HA S.R. Relationship between non-point source pollution and Korean green factor, Terr. Atmos. Ocean. Sci. 26, 341, 2015.
• 22. HU H., HUANG G. Monitoring of non-point source pollutions from an agriculture watershed in South China. Journal of Water, 2014.
• 23. CHEN J.N. Nonpoint Source Pollution Control – Case Studies in Dianchi Lake Catchments, China Environmental Science Press, Beijing, 2009.
• 24. CHEN H., TENG Y., WANG J. Load estimation and source apportionment of nonpoint source nitrogen and phosphorus based on integrated application of SLURP model, ECM, and RUSLE: a case study in the Jinjiang River, China. Environmental monitoring and assessment, 185 (2), 2009, 2013.
• 25. ZHAI X., ZHANG Y., WANG X., XIA J. LIANG T. Non-point source pollution modelling using Soil and Water Assessment Tool and its parameter sensitivity analysis in Xin’anjiang catchment, China. Hydrol. Process. 28, 1627, 2014.
• 26. PEGRAM G.C., BATH A.J. Role of non-point sources in the Development of a water quality Management plan for the Mgeni river catchment. Wat. Sci. Tech, 32 (5-6), 175, 1995.
• 27. XIA J., ZHAI X., ZHANG Y. Progress in the Research of Water Environmental Nonpoint Source Pollution Models. Progress in Geography, 31, 941, 2012.
• 28. XU H.S., XU Z.X., LIU P. Estimation of Nonpoint Source Pollutant Loads and Optimization of the Best Management Practices (BMPs) in the Zhangweinan River Basin. Environmental Science, 3, 10, 2013.
• 29. QIU Z. Comparative assessment of stormwater and nonpoint source pollution best management practices in suburban watershed management. Water, 5 (1), 280, 2013.
• 30. WU Y., CHEN J. Investigating the effects of point source and nonpoint source pollution on the water quality of the East River (Dongjiang) in South China. Ecological Indicators, 32, 294, 2013.
• 31. WU L., LIU X., MA X.Y. Spatio-temporal variation of erosion-type non-point source pollution in a small watershed of hilly and gully region, Chinese Loess Plateau. Environmental Science and Pollution Research, 23 (11), 10957, 2016.
• 32. PIMENTEL D. World soil erosion and conservation. Cambridge: Cambridge University Press. (Ed.), 1993.
• 33. BENEDINI M., TSAKIRIS G. Water quality modelling for rivers and streams. Springer Science & Business Media, 2013.
• 34. SHARMA D., KANSAL A. Assessment of river quality models: a review. Reviews in Environmental Science and Bio/Technology, 12, 285, 2013.
• 35. WANG Q., LI S., JIA P., QI C., DING F. A review of surface water quality models. The Scientific World Journal, 2013.
• 36. MAMUN A.A., SALLEH M.N. Challenges in non-point source pollution – Sampling and testing. In Engineering and Technology (BICET 2014), 5th Brunei International Conference, 1-6. IET, 2014.
• 37. Li S., Zhuang Y., Zhang L., Du Y., Liu H. Worldwide performance and trends in nonpoint source pollution modeling research from 1994 to 2013: A review based on bibliometrics. Journal of Soil and Water Conservation, 69 (4), 121A, 2014.
• 38. LIU X., ZHANG L., HONG S. Global biodiversity research during 1900-2009: A bibliometric analysis. Biodiversity and Conservation, 20 (4), 807, 2011.
• 39. ZHUANG Y., NGUYEN T., NIU B., SHAO W., HONG S. Research trends in non point source during 1975-2010. In International Conference on Medical Physics and Biomedical Engineering, ed. D. Yang. Physics Procedia, 138, 2012.
• 40. SHOEMAKER L., DAI T., KOENIG J., HANTUSH M. TMDL model evaluation and research needs. National Risk Management Research Laboratory, US Environmental Protection Agency, 2005.
• 41. BORAH D.K, BERA M. Watershed-scale hydrologic and nonpoint-source pollution models: Review of mathematical bases. Transactions of the ASAE, 46 (6), 1553, 2003.
• 42. BORAH D.K., BERA M. Watershed-scale hydrologic and nonpoint-source pollution models: Review of applications. Transactions of the ASAE, 47 (3), 789, 2004.
• 43. KLIMENT Z., KADLEC J., LANGHAMMER J. Evaluation of suspended load changes using AnnAGNPS and SWAT semi-empirical erosion models. Catena, 73, 286, 2008.
• 44. YOUNG R.A., ONSTAD C.A., BOSCH D.D., ANDERSON W.P. AGNPS: A nonpoint-source pollution model for evaluating agricultural watersheds. Journal of soil and water conservation, 44 (2), 168, 1989.
• 45. DE AUSSEN R., KALITA P.K., KOELLIKER J.K., MANKIN K.R. Application of AGNPS-ARC INFO interface model to an agricultural watershed of Kansas. In: ASAE Paper No. 983139 (St Joseph, eds.). ASAE, MI, USA, 1998.
• 46. BHUYAN S.J., KOELLIKER J.K., MARZEN L.J., HARRINGTON J. An integrated approach for water quality assessment of a Kansas watershed. Environmental Modelling Software, 18 (5), 473, 2003.
• 47. MOHAMMED H., YOHANNES F., ZELEKE G. Validation of agricultural non-point source (AGNPS) pollution model in Kori watershed, South Wollo. Ethiopia International Journal of Applied Earth Observation and Geoinformation, 6, 97, 2004.
• 48. LEON L.F., BOOTY W.G., BOWEN G.S., LAM D.C. Validation of an agricultural non-point source model in a watershed in southern Ontario. Journal of Agricultural Water Management, 65 (1), 59, 2004.
• 49. FINN M.P., USERY E.L., SCHEIDT D.J., JARONACK G.M., KRUPINSKI T.D. An interface between the agricultural non-point source (ANGPS) pollution model and the ERDAS imagine geographic information system (GIS). Geographic information sciences, 12 (1), 10, 2006.
• 50. BINGNER R.L., F.D. THEURER. Topographic factors for RUSLE in the continuous simulation watershed model for predicting agricultural, non-point source pollutants (AnnAGNPS), Soil erosion research for the 21st century. Proceedings of the International Symposium, Honolulu, Hawaii, USA, 3, 2001.
• 51. BEASLEY D.B., HUGGINS L.F. ANSWERS Users Manual. EPA-905/9-82-001, U.S. EPA, Region V. Chicago, IL, 1981.
• 52. DE ROO A.P.J., HAZELHOFF L. BURROUGH P.A. Soil erosion modelling using ‘answers’ and geographical information systems. Earth Surf. Process. Landforms, 14, 517, 1989.
• 53. NEITSCH S.L., ARNOLD J.G., KINIRY J.R., WILLIAMS J.R., Soil and Water Assessment Tool Theoretical Documentation Version 2009. edited, Texas Water Resources Institute, 2011.
• 54. LEONARD R.A., KNISEL W.G. Model selection for nonpoint source pollution and resource conservation. Proc. of the International Conference on Agriculture and Environment, Venice, Italy. E1-E18, 1984.
• 55. WILLIAMS J.R., NICKS A., ARNOLD J.G. Simulator for water resources in rural basins. Journal of Hydraulic Engineering, 111 (6), 970, 1985.
• 56. ABBASPOUR K.C., YANG J., MAXIMOV I., SIBER R., BOGNER K., MIELEITNER J., ZOBRIST J., SRINIVASAN R. Modelling hydrology and water quality in the pre-alpine/alpine Thur watershed using SWAT. Journal of hydrology, 333 (2), 413, 2007.
• 57. MARINGANTI C., CHAUBEY I., ARABI M., ENGEL B.. Application of a multi-objective optimization method to provide least cost alternatives for NPS pollution control. Environ Manage, 48, 448, 2011.
• 58. ULLRICH A., VOLK M. Application of the Soil and Water Assessment Tool (SWAT) to predict the impact of alternative management practices on water quality and quantity. Agricultural Water Management, 96, 1207, 2009.
• 59. BENAMAN J., SHOEMAKER C.A., HAITH D.A. Calibration and validation of soil and water assessment tool on an agricultural watershed in upstate New York. Journal of Hydrologic Engineering, 363, 2005.
• 60. MISEON L., GEUNAE P., MINJI P., JONGYOON P., JIWAN L., SEONGJOON K. Evaluation of non-point source pollution reduction by applying Best Management Practices using a SWAT model and QuickBird high resolution satellite imagery. Journal of Environmental Sciences, 22 (6), 826, 2010.
• 61. POUDEL D.D., LEE T., SRINIVASAN R., ABBASPOUR K., JEONG C.Y. Assessment of seasonal and spatial variation of surface water quality, identification of factors associated with water quality variability, and the modeling of critical nonpoint source pollution areas in an agricultural watershed. Journal of Soil and Water Conservation, 68 (3), 155, 2013.
• 62. HONG Q., SUN Z., CHEN L., LIU R., SHEN Z. Small-scale watershed extended method for nonpoint source pollution estimation in part of the Three Gorges Reservoir Region. Int J Environ Sci Technol, 9, 595, 2012.
• 63. SHEN Z.Y., CHEN L., HONG Q., QIU J.L., XIE H., LIU R.M. Assessment of nitrogen and phosphorus loads and causal factors from different land use and soil types in the Three Gorges Reservoir Area. Sci Total Environ. 454, 383, 2013b.
• 64. SHEN Z., CHEN L., HONG Q., XIE H., QIU J., LIU R. Vertical variation of nonpoint source pollutants in the Three Gorges Reservoir Region. Plos One, 8 (8), p.e71194, 2013c.
• 65. CROWDER B.M., YOUNG C.E. Modeling agricultural non-point source pollution for economic evaluation of the conestoga headwaters RCWP project. U.S Department of Agriculture, Economic Research Service, Natural resources Economic Division, washington, D.C. ERS Staff Report No. AGES850614: 70, 1985.
• 66. KAUPPI L. Testing the Application of CREAMS to Finnish Conditions. In: Svetlosanov, V., Knisel, W.G., editors. European and United States Case Studies in Application of the CREAMS Model. International Institute for Applied Systems Analysis. Laxenberg, Austria, 43, 1982.
• 67. ARNOLD J., WILLIAMS J., SINGH V. SWRRB-a watershed scale model for soil and water resources management, Computer models of watershed hydrology, 847, 1995.
• 68. BARNWELL T.O., JOHANSON R. HSPF: A comprehensive package for simulation of watershed hydrology and water quality. In: Nonpoint Pollution Control: Tools and Techniques for the Future. Interstate Commission on the Potomac River Basin, 1055 First Street, Rockville, MD 20850, 1981.
• 69. RIBAROVA I., NINOVB P., COOPER D. Modeling nutrient pollution during a first flood event using HSPF software: Iskar River case study, Bulgaria. Ecol Mod, 211, 241, 2008.
• 70. TZORAKI O., NIKOLAIDIS N.P. A generalized framework for modeling the hydrologic and biogeochemical response of a Mediterranean temporary river basin. J. Hydrology, 346, 112, 2007.
• 71. CHO J., BARONE V.A., MOSTAGHIMI S. Simulation of land use impacts on groundwater levels and streamflow in a Virginia watershed. Agri Wat Manag, 96, 1, 2009.
• 72. MARTIN J.L., WOOL T., OLSON R. A dynamic onedimensional model of hydrodynamics and water quality EPD-RIV1 Version 1.0. User’s manual by Roy Burke III, Georgia Environmental Protection Division, Atlanta, Georgia, 2002.
• 73. LEON L.F., SOULIS E.D., KOUWEN N., FARQUHAR G.J. Non-point source pollution: a distributed water quality modelling approach. Journal Water Research, 35 (4), 997, 2001.
• 74. JAIN C.K. Application of chemical mass balance approach to determine nutrient loading. Hydrological sciences journal, 45 (4), 577, 2000.
• 75. NOVOTNY V., OLEM H. Water quality: prevention, identification and management of diffuse pollution. Van Nostrand-Reinhold: New York, 1994.

Identyfikatory

DOI

10.15244/pjoes/76497