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dc.contributor.authorGallo Sánchez, Lina J.-
dc.contributor.authorFlórez-Molina, María T.-
dc.contributor.authorParra Sánchez, Luis N.-
dc.date.accessioned2021-10-15T15:28:52Z-
dc.date.available2021-10-15T15:28:52Z-
dc.date.issued2015-01-07-
dc.identifier.urihttps://repositorio.accefyn.org.co/handle/001/822-
dc.description.abstractLas técnicas de espectrometría y el análisis de las diatomeas permitieron excelentes ajustes para la estimación de la variación de las concentraciones de materia orgánica mediante el método de pérdida por ignición y la determinación de fósforo total y nitrógeno total Kjeldahl durante el tiempo de operación de los embalses de La Fe (37 años), Ríogrande II (21 años) y Porce II (9 años), localizados en Antioquia, Colombia. Los cambios en la paleo-geoquímica de los embalses no se acercaron al comportamiento esperado en los lagos, es decir, a una disminución exponencial en relación con la profundidad, lo cual se debe, en parte, a factores como la diagénesis tardía del sedimento y a la operación o manejo de los embalses. Sin embargo, las diatomas presentes en el sedimento, así como la diversidad y el promedio anual del pH en la columna de agua, mostraron cambios significativos con respecto al llenado inicial del embalse y hasta el 2010 (año de recolección de los datos). En los embalses de La Fe y Ríogrande II se observó una disminución en la buena calidad inicial del agua, mientras que en Porce II estos indicadores mostraron una permanente eutrofización del sistema.spa
dc.description.abstractWe present the results of a multiproxy reconstruction of the variation of organic matter using the loss-on-ignition method, and total phosphorus and Kjeldahl nitrogen during the operation of La Fe (37 years), Ríogrande II ( 21 years) and Porce II (9 years) reservoirs in Antioquia, Colombia, based on the analysis of diatoms and using near-infrared spectroscopy. Changes in reservoir paleo-geochemistry did not approach the expected behavior for lakes, i.e., an exponential decrease with depth, due in part to factors such as a late diagenesis and the management of the reservoirs. However, diatoms present in the sediment, along with diversity and the annual average pH of the water column, showed significant changes from the initial filling of the reservoirs until 2010 (year in which the data were collected). In La Fe and Ríogrande II reservoirs, a decrease in water quality was observed, whereas in Porce II reservoir these indicators showed the continuing eutrophication of the system.eng
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dc.publisherAcademia Colombiana de Ciencias Exactas, Físicas y Naturalesspa
dc.rightsCreative Commons Attribution-NonCommercial-ShareAlike 4.0 Internationalspa
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dc.titleReconstrucción de las concentraciones de materia orgánica y nutrientes mediante espectrometría y análisis de diatomeas en tres embalses de Antioquiaspa
dc.typeArtículo de revistaspa
dcterms.audienceEstudiantes, Profesores, Comunidad científicaspa
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dcterms.referencesEsteves, E. 1998. Fundamentos de Limnología. (II ed.). Finep, Río de Janeiro: Editorial Interciencia.spa
dcterms.referencesHall, R.I. & Smol, J.P. 1999. Diatoms as indicators of lake eutroph-ication. In E.F. Stoermer & J.P. Smol (eds.). The Diatoms: Applications for the Environmental and Earth Sciences. Cambridge, UK: Cambridge University Press. pp. 128–168spa
dcterms.referencesHumane, S.K., Bokade, P.R., Humane, S.S., Wankhade, A.S.2010. Trophic status and ecological studies of the Ambazari Lake, Nagpur, Maharashstra, based on sedimentary diatoms. Current Science. 99 (6): 816-822.spa
dcterms.referencesKorsman, T., Nilsson, M.B., Landgren, K., Renberg, I. 1999. Spatial variability in surface sediment composition charac-terized by near-infrared (NIR) reflectance spectroscopy. Journal of Paleolimnology.21: 61–71spa
dcterms.referencesLarrahondo, J.E. & Palau, F. 2001. Espectroscopia de infrarrojo cercano NIR. Principios generales [serie Procesos Indus-triales, Nº 1]. Cali, Colombia: Cenicaña.Lowe, R.L. 1974. Environment requirements and pollution toler-ance of freshwater diatoms. Cincinnati, Ohio, USA: U.S.: Environmental Protection Agency.Machain, M.L. & Ruiz, C. 2006. Indicadores biofísicos en sedimentos acuáticos. En Especies, Espacios y Riesgos, cap. 13. I edición. México: Instituto Nacional de Ecología. Malley, D.F., Williams P.C., Hauser, B.W., Hall, J. 1996. Prediction of organic carbon, nitrogen and phosphorus in freshwater sediments using near infrared reflectance spectroscopy. In A.M. Davies & Williams, P. (eds). Near Infrared Spectroscopy. The Future Waves. Chichester, U.K: NIR Publications. pp. 691–699.Malley, D.F. & Williams, P.C. 1997. Use of near-infrared reflectance spectroscopy in prediction of heavy metals in freshwater sediment by their association with organic matter. Environmental Science of Technology. 31: 3461–3467.Malley, D.F. 1998. Near-infrared spectroscopy as a potential method for routine sediment analysis to improve rapidity and efficiency. Water Science and Technology. 37: 181-188.Malley, D.F., Rönicke, H., Findlay, D.L., Zippel, B. 1999. Feasibility of using near-infrared reflectance spectroscopy for the analysis of C, N, P, and diatoms in lake sediments. Journal of Paleolimnology. 21: 295–306.Malley, D.F., Lockhart, L., Wilkinson, P., Hauser, B. 2000. Determination of carbon, carbonate, nitrogen, and phos-phorus in freshwater sediments by near-infrared reflectance spectroscopy: Rapid analysis and a check on conventional analytical methods. Journal of Paleolimnology. 24: 415–425.Malley, D.F., Mcclure, C., Martin, P. D., Firlotte, N., Goldsborough, G., Sheppard, M. 2002. Evaluation of Near-infrared Spectroscopy as a Rapid Method for Estimating the Carbon Stored per Unit Area in a Wetland. Winnipeg: PDK Projects, Inc. Morales, S. & Salazar, M. 2012. Diatomeas perifíticas de lagos con diferente estado trófico en el departamento del Cauca (Colombia). Luna Azul. 35: 10-27.Nürnberg, G.K. 1984. The prediction of internal phosphorus load in lakes with anoxic hypolimnia. Limnology and Oceanography. 29: 111-124.Osborne, B.G. & Fearn, F. 1986. Near Infrared Spectroscopy in Food Analysis. New York: John Wiley.Reitzel, K., Ahlgren, J., DeBrabandere, H., Waldebäck, M., Gogoll, A., Tranvik, L., Rydin, E. 2007. Degradation rates of organic phosphorus in lake sediment. Biogeochemistry. 82: 15-28.Rosén, P., Dåbakk, E., Renberg, I., Nilsson, M., Hall, R. 2000. Near-infrared spectrometry (NIRS), a new tool to infer past climatic changes from lake sediments. The Holocene. 10: 161–66.Rosén, P., Hall, R., Korsman, T. & Renberg, I. 2000. Diatom transfer-functions for quantifying past air temperature, pH and total organic carbon concentration from lakes in northern Sweden. Journal of Paleolimnology. 24: 109–23. Rosén, P., Segerstro, U.L.F., Eriksson, L., Renberg, I, Birks, H.J.B. 2001. Holocene climatic change reconstructed from diatoms, chironomids, pollen and near-infrared spectros-copy at an alpine lake (Sjuodjijaure) in northern Sweden. The Holocene. 11 (5): 551–562.spa
dcterms.referencesLowe, R.L. 1974. Environment requirements and pollution toler-ance of freshwater diatoms. Cincinnati, Ohio, USA: U.S.: Environmental Protection Agencyspa
dcterms.referencesMachain, M.L. & Ruiz, C. 2006. Indicadores biofísicos en sedimentos acuáticos. En Especies, Espacios y Riesgos, cap. 13. I edición. México: Instituto Nacional de Ecologíaspa
dcterms.referencesMalley, D.F., Williams P.C., Hauser, B.W., Hall, J. 1996. Prediction of organic carbon, nitrogen and phosphorus in freshwater sediments using near infrared reflectance spectroscopy. In A.M. Davies & Williams, P. (eds). Near Infrared Spectroscopy. The Future Waves. Chichester, U.K: NIR Publications. pp. 691–699.spa
dcterms.referencesMalley, D.F. & Williams, P.C. 1997. Use of near-infrared reflectance spectroscopy in prediction of heavy metals in freshwater sediment by their association with organic matter. Environmental Science of Technology. 31: 3461–3467.spa
dcterms.referencesMalley, D.F. 1998. Near-infrared spectroscopy as a potential method for routine sediment analysis to improve rapidity and efficiency. Water Science and Technology. 37: 181-188spa
dcterms.referencesMalley, D.F., Rönicke, H., Findlay, D.L., Zippel, B. 1999. Feasibility of using near-infrared reflectance spectroscopy for the analysis of C, N, P, and diatoms in lake sediments. Journal of Paleolimnology. 21: 295–306spa
dcterms.referencesMalley, D.F., Lockhart, L., Wilkinson, P., Hauser, B. 2000. Determination of carbon, carbonate, nitrogen, and phos-phorus in freshwater sediments by near-infrared reflectance spectroscopy: Rapid analysis and a check on conventional analytical methods. Journal of Paleolimnology. 24: 415–425spa
dcterms.referencesMalley, D.F., Mcclure, C., Martin, P. D., Firlotte, N., Goldsborough, G., Sheppard, M. 2002. Evaluation of Near-infrared Spectroscopy as a Rapid Method for Estimating the Carbon Stored per Unit Area in a Wetland. Winnipeg: PDK Projects, Inc.spa
dcterms.referencesMorales, S. & Salazar, M. 2012. Diatomeas perifíticas de lagos con diferente estado trófico en el departamento del Cauca (Colombia). Luna Azul. 35: 10-27spa
dcterms.referencesNürnberg, G.K. 1984. The prediction of internal phosphorus load in lakes with anoxic hypolimnia. Limnology and Oceanography. 29: 111-124spa
dcterms.referencesOsborne, B.G. & Fearn, F. 1986. Near Infrared Spectroscopy in Food Analysis. New York: John Wiley.spa
dcterms.referencesReitzel, K., Ahlgren, J., DeBrabandere, H., Waldebäck, M., Gogoll, A., Tranvik, L., Rydin, E. 2007. Degradation rates of organic phosphorus in lake sediment. Biogeochemistry. 82: 15-28spa
dcterms.referencesRosén, P., Dåbakk, E., Renberg, I., Nilsson, M., Hall, R. 2000. Near-infrared spectrometry (NIRS), a new tool to infer past climatic changes from lake sediments. The Holocene. 10: 161–66.spa
dcterms.referencesRosén, P., Hall, R., Korsman, T. & Renberg, I. 2000. Diatom transfer-functions for quantifying past air temperature, pH and total organic carbon concentration from lakes in northern Sweden. Journal of Paleolimnology. 24: 109–23spa
dcterms.referencesRosén, P., Segerstro, U.L.F., Eriksson, L., Renberg, I, Birks, H.J.B. 2001. Holocene climatic change reconstructed from diatoms, chironomids, pollen and near-infrared spectros-copy at an alpine lake (Sjuodjijaure) in northern Sweden. The Holocene. 11 (5): 551–562spa
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dc.rights.accessrightsinfo:eu-repo/semantics/openAccessspa
dc.type.driverinfo:eu-repo/semantics/articlespa
dc.type.versioninfo:eu-repo/semantics/publishedVersionspa
dc.rights.creativecommonsAtribución-NoComercial 4.0 Internacional (CC BY-NC 4.0)spa
dc.identifier.doihttps://doi.org/10.18257/raccefyn.67-
dc.subject.proposalMateria orgánicaspa
dc.subject.proposalOrganic mattereng
dc.subject.proposalNitrógenospa
dc.subject.proposalNitrogeneng
dc.subject.proposalFósforospa
dc.subject.proposalPhosphoruseng
dc.subject.proposalEspectrocopíaspa
dc.subject.proposalSpectroscopyeng
dc.subject.proposalEspectroscopia en el infrarrojo cercanospa
dc.subject.proposalNear-infrared spectroscopyeng
dc.subject.proposalSedimentosspa
dc.subject.proposalSedimenteng
dc.type.coarhttp://purl.org/coar/resource_type/c_6501spa
dc.relation.ispartofjournalRevista de la Academia Colombiana de Ciencias Exactas, Físicas y Naturalesspa
dc.relation.citationvolume38spa
dc.relation.citationstartpage409spa
dc.relation.citationendpage416spa
dc.publisher.placeBogotá, Colombiaspa
dc.contributor.corporatenameAcademia Colombiana de Ciencias Exactas, Físicas y Naturalesspa
dc.coverage.regionAntioquia, Colombia-
dc.relation.citationissue149spa
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