Estimación, Manejo y Control de la Contaminación No Puntual por Escorrentía Superficial Ganadera: Una Revisión de literatura

• Pérez Sane, Monica ^[1] ; Torres Pardo, Camilo ^[1] ; Lara Borrero, Jaime ^[1]
  1. [1] Pontífica Universidad Javeriana

     Pontífica Universidad Javeriana

     Colombia

     
• Localización: Revista Politécnica, ISSN-e 2477-8990, Vol. 53, Nº. 1, 2024 (Ejemplar dedicado a: Revista Politécnica), págs. 111-123
• Idioma: español
• DOI: 10.33333/rp.vol53n1.10
• Títulos paralelos:
  • Estimation, Management, and Control of Non-Point Source Pollution from Livestock Runoff: A Literature Review
• Enlaces
  • Texto completo
• Resumen
  • español

    Los nutrientes, como el nitrógeno y el fósforo generan, entre otros impactos, la eutrofización en los cuerpos de agua. Estos impactos son principalmente causados por actividades agrícolas como la ganadería, debido a la aplicación de fertilizantes y/o al estiércol de las vacas. Los nutrientes transportados por la escorrentía llegan a los cuerpos de agua y generan contaminación. Esta problemática ha sido abordada desde la década de los 60, no obstante, se ha logrado poco avance en este tema. Los avances están relacionados con la estimación del aporte de nutrientes de forma teórica y a través de simulaciones, debido a los altos costos que implica tomar datos en el campo. También se han realizado esfuerzos en la implementación de Buenas Prácticas de Gestión para el manejo de las fuentes no puntuales, pero existe poca evidencia de la eficiencia de cada una de estas prácticas. Por otro lado, pese a la falta de información científica necesaria para formular políticas, se ha demostrado que la vía normativa puede ser el mejor mecanismo para controlar la contaminación por fuentes no puntuales. En este artículo, se presenta una revisión de estos tres componentes luego del análisis bibliométrico, estableciendo lo que se conoce actualmente y las brechas de información. Primero, se abordan los avances en la estimación del aporte de las fuentes no puntuales, segundo se presentan las Buenas Prácticas de Gestión, y tercero, se exponen los avances en materia de políticas para el control de la contaminación no puntual.

  • English

    Nutrients, like nitrogen and phosphorus generate, among other impacts, eutrophication in water bodies. These impacts are mainly caused by agricultural activities such as livestock farming, due to the application of fertilizers and/or cow manure. The nutrients transported by runoff reach water bodies and generate pollution. This issue has been addressed since the 1960s; however, little progress has been made in this area. The progress is related to estimating nutrient contributions theoretically and through simulations, due to the high costs of collecting field data. Efforts have also been made to implement Good Management Practices for the management of non-point sources, but significant efficiency for each of these practices has not been demonstrated. On the other hand, despite the lack of necessary scientific information to formulate policies, it has been shown that the regulatory route can be the best mechanism for controlling non-point source pollution. This article presents a review of these three components after a bibliometric analysis, establishing what is currently known and the information gaps. First, advances in estimating the contributions of non-point sources are addressed, second Good Management Practices are presented, and third advances in policies for controlling non-point source pollution are discussed.

     

• Referencias bibliográficas
  • Abdelwahab, O. M. M., Ricci, G. F., De Girolamo, A. M., & Gentile, F. (2018). Modelling soil erosion in a Mediterranean watershed: Comparison...
  • Amin, M. G. M., Karsten, H. D., Veith, T. L., Beegle, D. B., & Kleinman, P. J. (2018). Conservation dairy farming impact on water quality...
  • Arnold, J. G., Srinivasan, R., Muttiah, R. S., & Williams, J. R. (1998). Large Area Hydrologic Modeling and Assessment Part I: Model Development1....
  • Bai, X., Shen, W., Wang, P., Chen, X., & He, Y. (2020). Response of Non-point Source Pollution Loads to Land Use Change under Different...
  • Ballantine, D. J., & Davies-Colley, R. J. (2013). Nitrogen, phosphorus and E. coli loads in the Sherry River, New Zealand. New Zealand...
  • Bird, S. C., & Drizo, A. (2009). Investigations on phosphorus recovery and reuse as soil amendment from electric arc furnace slag filters....
  • Carpenter, S. R., Caraco, N. F., Correll, D. L., Howarth, R. W., Sharpley, A. N., & Smith, V. H. (1998). Nonpoint Pollution of Surface...
  • Chen, D., Li, H., Zhang, W., Pueppke, S. G., Pang, J., & Diao, Y. (2020). Spatiotemporal Dynamics of Nitrogen Transport in the Qiandao...
  • Chen, H., Teng, Y., & Wang, J. (2013). Load estimation and source apportionment of nonpoint source nitrogen and phosphorus based on integrated...
  • Chen, L., Wang, Y., Yang, N., Zhu, K., Yan, X., Bai, Z., Zhai, L., & Shen, Z. (2023). Improving crop-livestock integration in China using...
  • Chen, X., Liu, X., Peng, W., Dong, F., Huang, Z., & Wang, R. (2017). Non-point source nitrogen and phosphorus assessment and management...
  • Chen, X.-K., Liu, X.-B., Peng, W.-Q., Dong, F., Huang, Z.-H., Feng, S.-X., & Wang, R.-N. (2018). Estimation of and Control Strategies...
  • De Lima Barros, A. M., Do Carmo Sobral, M., & Gunkel, G. (2013). Modelling of point and diffuse pollution: Application of the Moneris...
  • Ding, X., Shen, Z., Hong, Q., Yang, Z., Wu, X., & Liu, R. (2010). Development and test of the Export Coefficient Model in the Upper Reach...
  • Doole, G. J. (2012). Cost-effective policies for improving water quality by reducing nitrate emissions from diverse dairy farms: An abatement-cost...
  • Drizo, A., Johnston, C., & Guðmundsson, J. (2022). An Inventory of Good Management Practices for Nutrient Reduction, Recycling and Recovery...
  • Drizo, A., & Picard, H. (2012). Systems and methods for removing phosphorous from wastewater (United States Patent US20120048806A1). https://patents.google.com/patent/US20120048806A1/en/und
  • EPA. (2013). Introducción a la Ley de Agua Limpia. United Satate Environmental Protection Agency. https://cfpub.epa.gov/watertrain/pdf/modules/Introduccion_a_la_Ley_de_Aqua_Limpia.pdf
  • Gao, W., Dai, A., Wu, J., Li, Y., Hou, J., Wang, X., & Li, K. (2023). Hydrological status of the Dagu River Basin and management suggestions...
  • Geng, R., & Sharpley, A. N. (2019). A novel spatial optimization model for achieve the trad-offs placement of best management practices...
  • Guo, Y., Wang, X., Melching, C., & Nan, Z. (2022). Identification method and application of critical load contribution areas based on...
  • Hou, L., Zhou, Z., Wang, R., Li, J., Dong, F., & Liu, J. (2022). Research on the Non-Point Source Pollution Characteristics of Important...
  • JiaKe, L., HuaiEn, L., & YaJiao, L. (2009). Development of study on AnnAGNPS model and its application. Journal of Northwest A & F...
  • Johnes, P. J. (1996). Evaluation and management of the impact of land use change on the nitrogen and phosphorus load delivered to surface...
  • Kanter, D. R., Musumba, M., Wood, S. L. R., Palm, C., Antle, J., Balvanera, P., Dale, V. H., Havlik, P., Kline, K. L., Scholes, R. J., Thornton,...
  • Li, A.-L., Haitao, C., Yuanyuan, L., Qiu, L., & Wenchuan, W. (2020). Simulation of nitrogen pollution in the Shanxi Reservoir watershed...
  • Liu, X., Li, D., Zhang, H., Cai, S., Li, X., & Ao, T. (2015). Research on Nonpoint Source Pollution Assessment Method in Data Sparse Regions:...
  • Logan, T. J. (1993). Agricultural best management practices for water pollution control: Current issues. Agriculture, Ecosystems & Environment,...
  • Mohamoud, Y. M., & Prieto, L. M. (2012). Effect of Temporal and Spatial Rainfall Resolution on HSPF Predictive Performance and Parameter...
  • Niu, S., Guerra, H. B., Chen, Y., Park, K., & Kim, Y. (2013). Performance of a vertical subsurface flow (VSF) wetland treatment system...
  • Qiu, J., Shen, Z., Chen, L., & Hou, X. (2019). Quantifying effects of conservation practices on non-point source pollution in the Miyun...
  • Roygard, J. K. F., McArthur, K. J., & Clark, M. E. (2012). Diffuse contributions dominate over point sources of soluble nutrients in two...
  • Sharara, M., Sampat, A., Good, L., Smith, A., Porter, P., Zavala, V., Larson, R., & Runge, T. (2017). Spatially explicit methodology for...
  • Shen, Z., Liao, Q., Hong, Q., & Gong, Y. (2012). An overview of research on agricultural non-point source pollution modelling in China....
  • Skidmore, M., Andarge, T., & Foltz, J. (2023). Effectiveness of local regulations on nonpoint source pollution: Evidence from Wisconsin...
  • Soranno, P. A., Hubler, S. L., Carpenter, S. R., & Lathrop, R. C. (1996). Phosphorus Loads to Surface Waters: A Simple Model to Account...
  • Stackpoole, S. M., Stets, E. G., & Sprague, L. A. (2019). Variable impacts of contemporary versus legacy agricultural phosphorus on US...
  • Sweeten, J. M., & Reddell, D. L. (1976). NONPOINT SOURCES: STATE-OF-THE-ART OVERVIEW. Paper - American Society of Agricultural Engineers,...
  • Tanik, A., Ozalp, D., & Seker, D. Z. (2013). Practical estimation and distribution of diffuse pollutants arising from a watershed in Turkey....
  • Tong, X., Zhou, Y., Liu, J., Qiu, P., & Shao, Y. (2022). Non-point source pollution loads estimation in Three Gorges Reservoir Area based...
  • Uribe, N. (2005). Conceptos basicos y guia rapida para el usuario. https://swat.tamu.edu/media/46967/swat2005-tutorial-spanish.pdf
  • US EPA, O. (2015, febrero 19). Hydrological Simulation Program—FORTRAN (HSPF) [Data and Tools]. https://www.epa.gov/ceam/hydrological-simulation-program-fortran-hspf
  • Uusitalo, R., Ylivainio, K., Hyväluoma, J., Rasa, K., Kaseva, J., Nylund, P., Pietola, L., & Turtola, E. (2012). The effects of gypsum...
  • Vanotti, M. B., Szogi, A. A., & Fetterman, L. M. (2010). Wastewater treatment system with simultaneous separation of phosphorus and manure...
  • Vollenweider, U. E. N. C. for E. (1968). Scientific fundamentals of the eutrophication of lakes and flowing waters, with particular reference...
  • Wang, H., Wu, Z., & Hu, C. (2015). A Comprehensive Study of the Effect of Input Data on Hydrology and non-point Source Pollution Modeling....
  • Wang, M., Chen, L., Wu, L., Zhang, L., Xie, H., & Shen, Z. (2022). Review of Nonpoint Source Pollution Models: Current Status and Future...
  • White, M., Harmel, D., Yen, H., Arnold, J., Gambone, M., & Haney, R. (2015). Development of Sediment and Nutrient Export Coefficients...
  • Wu, L., Long, T.-Y., & Cooper, W. J. (2012). Simulation of spatial and temporal distribution on dissolved non-point source nitrogen and...
  • Wu, M., Tang, X., Li, Q., Yang, W., Jin, F., Tang, M., & Scholz, M. (2013). Review of ecological engineering solutions for rural non-point...
  • Xie, H., & Lian, Y. (2013). Uncertainty-based evaluation and comparison of SWAT and HSPF applications to the Illinois River Basin. Journal...
  • Xue, J., Wang, Q., & Zhang, M. (2022). A review of non-point source water pollution modeling for the urban–rural transitional areas of...
  • Yang, J., Wang, Y., Fang, S., Qiang, Y., Liang, J., Yang, G., & Feng, Y. (2020). Evaluation of livestock pollution and its effects on...
  • Zhang, T., Yang, Y., Ni, J., & Xie, D. (2020). Best management practices for agricultural non-point source pollution in a small watershed...
  • Zhang, Y., Griffith, B., Granger, S., Sint, H., & Collins, A. L. (2022). Tackling unintended consequences of grazing livestock farming:...
  • Zhao, C., Li, M., Wang, X., Liu, B., Pan, X., & Fang, H. (2022). Improving the accuracy of nonpoint-source pollution estimates in inland...