Abstract
Balamtetik is the receiving body of the Rio Grande de Comitán and is located just at the outskirts of the Montebello National Park, Chiapas, México. Multi-elemental, infrared spectra, 137Cs, 210Pb, and diatom analyses in a 75-cm sediment core were used to reconstruct the recent disturbance history of the lake. The sequence chronology, based mostly on 137Cs profiles, allowed to infer high sedimentation rates in Balamtetik (~ 7 mm/year) and a nearly cyclic series of disturbance events that can be related to anthropogenic causes such as deforestation and increased development of agriculture and urban areas at local and regional scale. These disturbance events show high local and regional erosion (high Ca, TIC, and Ti), soil organic matter (IR spectra), eutrophication (high P and diatoms), and anoxic bottom water conditions (low Mn) and can be dated to the early 1950s, the late 1950s, and from the 1980s until the 2000s. The entrance of wastewaters is related with an increase in salinity inferred by the diatom record and the organic matter type. The first two disturbance events are related to changes in land use during the agrarian reform that started during the 1940s; the last event is related with the increase in local population and the introduction of intensive agriculture. This last phase of disturbance corresponds with the reports of fish mortality events around 2003; however, high lake turbidity and anoxic bottom waters seem to have been established since the 1980s. The record from Lake Balamtetik also shows that during the intermediate periods, there was a recovery of the lake and its catchment; however, the future trends might be different, as the increase in the speed of organic matter and nutrients arrival to the lake reduces its resilience.
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References
Alaoui-Mhamdi M, Dhib A, Bouhaddioui A, Ziadi B, Turki S, Aleya T (2014) Assessment of nitrogen and phosphate balance and the roles of bacteria and viruses at the water-sediment interface in the Allal El Fassi reservoir (Morocco). Environ Monit Assess 186(9):5817–5829
Alcocer J, Oseguera LA, Sánchez G, González CG, Martínez JR, González R (2016) Bathymetric and morphometric surveys of the Montebello lakes, Chiapas. J Limnol 75:56–65
Battarbee RW (2000) Paleolimnological approaches to climate change, with special regard to the biological record. Quat Sci Rev 19:107–124
Battarbee RW, Jones VJ, Flower RJ, Cameron NG, Bennion H, Carvalho L, Juggins S (2001) Diatoms. In: Smol JP, Birks HJB, Last W (eds) Tracking environmental change using lake sediments Vol 3: terrestrial, algal and siliceous indicators. Kluwer, Dordrecht, pp 155–202
Bennion H (1995) Surface-sediment diatom assemblages in shallow, artificial, enriched ponds, and implications for reconstructing trophic status. Diatom Research 10:1–19
Bornemann L, Welp G, Dyar MD, Brown AJ (2008) Reflectance and emission spectroscpoy study of four groups of phyllosilicates; spectites, kaolinites serpentites, chlorites and micas. Clay Miner 43:35–54
Caballero M, Vázquez G, Lozano-García S, Rodríguez A, Sosa-Nájera S, Ruiz-Fernández AC, Ortega B (2006) Present limnological conditions and recent (ca. 340 yr) palaeolimnology of a tropical lake in the Sierra de Los Tuxtlas, Eastern Mexico. J Paleolimnol 35:83–97
CFE (2012) Estudio para conocer la calidad del agua de las lagunas de Montebello, Tomo I. Hidrometeorología. Comisión Federal de Electricidad, México, 45pp
CONANP (2007) Comisión Nacional de Áreas Naturales Protegidas y Secretaría del Medio Ambiente y Recursos Naturales (CONANP-SEMARNAT), “Programa de Conservación y Manejo Parque Nacional Lagunas de Montebello, México” http://www.conanp.gob.mx/ que_hacemos/pdf/programas_manejo/ Final_Montebello.pdf
Davidson TA, Jeppesen E (2013) The role of palaeolimnology in assessing eutrophication and its impact on lakes. J Paleolimnol 49:391–410
Durán CL, Escolero OF, Muñoz EFM, Castillo MCS, Rodríguez GSR (2014) Cartografía geomorfológica a escala 1:50000 del Parque Nacional Lagunas de Montebello, Chiapas (México). Bol Soc Geol Mex 66:263–277
Fritz S (2007) Salinity and climate reconstruction from diatoms in continental lake deposits. In: Elias SA (ed) Encyclopedia of quaternary science. Elsevier, Oxford, pp 514–522
García MT, Bórquez LC (2006) Chiapas: los cambios en la tenencia de la tierra. Argumentos (Mex) 19:51
Guilizzoni RA, Marchetto A, Lami NG, Cameron RG, Appleby NL et al (1987) Measured particle bound activity size-distribution, deposition velocity, and activity concentration in rainwater after the Chernobyl accident. J Aerosol Sci 18:681–684
Hall RI, Smol JP (1999) Diatoms as indicators of lake eutrophication. In: Stoermer EF, Smol J (eds) The diatoms: applications for the environmental and earth sciences. Cambrdige University Press, Cambridge, pp 128–168
Instituto Nacional de Estadística y Geografía INEGI (1985) Carta Geológica. Las Margaritas. 1:250,000. (E15-12-D15-3)
Instituto Nacional de Estadística y Geografía INEGI (2018) Censos de Población y Vivienda, http://www.beta.inegi.org.mx (downloaded September 5, 2018)
Jeong KS, Recknagel F, Joo GJ (2006) Prediction and elucidation of population dynamics of the blue-green algae microcystis aeruginosa and the diatom Stephanodiscus hantzschii in the Nakdong River-reservoir system (South Korea) by a recurrent artificial neural network. In: Recknagel F (ed) Ecological Informatics: Scope, Techniques and Applications. Springer Berlin Heidelberg, Berlin, Heidelberg, pp 255–273
Kaiser M, Walter K, Ellerbrock RH, Sommer M (2011) Effects of land use and mineral characteristic on the organic carbon content, and the amount and composition of Na-pyrophosphate-soluble organic matter, in substance soil. Eur J Soil Sci 62:226–236
Kolmakov VI, Gaevskii NA, Ivanova EA, Dubovskaya OP, Gribovskaya IV, Kravchuk ES (2002) Comparative analysis of ecophysiological characteristics of Stephanodiscus hantzschii Grun. In the periods of its bloom in recreational water bodies. Russ J Ecol 33:97–103
Krammer K, Lange-Bertalot H (1991-1999) Süsswasserflora von Mitteleuropa (Teil 1-4). Stuttgart-Jena: VEB Gustav Fischer Verlag, Germany
Macias JL (2005) Geología e historia eruptiva de algunos de los grandes volcanes activos de México. Boletin de la Sociedad Geológica Mexicana 57:379–424
March MIJ, Flamenco SA (1996) Evaluación rápida de la deforestación en las áreas naturales protegidas de Chiapas (1970-1993). The nature conservancy, Ecosur, Usaid. 66 http://200.23.34.25/Art tnc.pdf
Meyers PA (2006) An overview of sediment organic matter records of human eutrophication in the Laurentian Great Lakes region. Water Air Soil Pollut 6:453–463
Mora L, Bonifaz R, López-Martínez R (2016) Unidades geomorfológicas de la cuenca del Río Grande de Comitán, Lagos de Montebello, Chiapas-México. Bol Soc Geol Mex 68:377–394
Mulligan CN, Yong RN, Gibbs BF (2001) An overview of technology for heavy metal remediation of dredged sediments. J Hazard Mater 85:145–163
Ndebele Murisa MR, Musil CF, Raitt L (2010) A review of phytoplankton dynamics in tropical african lakes. S Afr J Sci 106:13–18
Novelo E, Tavera RL, Ibarra C (2007) Bacillariophyceae from karstic wetlands in Mexico. J. Cramer. Stuttgart Germany
Oldfield F, Appleby P (1984) Empirical testing of 210 Pb-dating models for lake sediments. In: Haword E, Lund JWG (eds) Lake sediments and environmental history. Leicester University Press, Leicester, pp 93–124
Oseguera L, Alcocer J (2015) Concentración y distribución vertical del carbono particulado (total y orgánico) en los lagos de Montebello, Chiapas. In "Estado Actual del Conocimiento del Ciclo del Carbono y sus Interacciones en México: Síntesis a 2014." (F. Paz and J. Wong, eds.), pp. 457–463. Programa Mexicano del Carbono, Texcoco
Payne RJ, Mitchell EAD (2009) How many is enough? Determining optimal count totals for ecological and palaeoecological studies of testate amoebae. J Paleolimnol 42:483–495
Pöllänen R, Valkama I, Toivonen H (1997) Transport of radioactive particles from the Chernobyl accident. Atmos Environ 31:3575–3590
Quezada- Meñetón JM (1987) El CretàcicoMedio Superior, y el lìmiteCretàcico superior Terciario Inferior de la Sierra de Chiapas. Boletìn de la Asociación Mexicana de Geólogos Petroleros 34:3–97
Ritchie JC, McHenry R (1975) Fallout Cs-137: a tool in conservation research. J Soil Water Conserv 30:283–286
Ritchie JC, McHenry R (1990) Application of radioactive fallout cesium-137 for measuring soil erosion and sediment accumulation rates and patterns: a review. J Environ Qual 19:215–233
Ruiz-Fernández AC, Hillaire-Marcel C (2009) 210Pb-derived ages for the reconstruction of terrestrial contaminant history into the Mexican Pacific coast: potential and limitations. Mar Pollut Bull 59:134–145
Tinti A, Tugnoli V, Bonora S, Francioso O (2015) Recent applications of vibration mid-infrared (IR) spectroscopy for studying soil components: a review. J Cent Eur Agric 16:1–22
Vera-Franco M N, Hernández-Victoria P, Alcocer J, Ardiles-Gloria V, Oseguera LV (2015) Concentración y distribución vertical de la clorofila-a fitoplanctónica en los lagos de Montebello, Chiapas. In: Tendencias de Investigación en Limnología tropical: Perspectivas universitarias en Latinoamérica Edition: 1Publisher: Asociación Mexicana de Limnología, A.C., Instituto de Ciencias del Mar y Limnología, UNAM, y Consejo Nacional de Ciencias y Tecnología Editors: J. Alcocer, M. Merino-Ibarra, E. Escobar-Briones
Walling DE, Bradley SB (1988) The use of caesium-137 measurements to investigate sediment delivery from cultivated areas in Devon, UK. Sediment budgets (proceedings of the Porto Alegre Symposium). IAHS Publ 174:325–335
Wei L, Kinouchi T, Yoshimura K, Velleux ML (2017) Modelling watershed-scale 137Cs transport in a forested catchment affected by the Fukushima Dai-ichi nuclear power plant accident. J Environ Radioact 171:21–33
Funding
This research was funded by the National Autonomous University of Mexico (UNAM) though Projects PAPIIT-IV200319 and PAPIIT-IN219215. The authors thank: Javier Tadeo, Fabiola Vega and Karina Cortés, the Laboratorio Nacional de Geoquímica y Mineralogía (LANGEM), the Laboratorio Universitario de Nanotecnología Ambiental (LUNA) UNAM and the Laboratorio de Geoquímica Analítica, Instituto de Geofísica, UNAM and Libia Hascibe Pérez-Bernal, at Laboratorio de Geoquímica Isotópica y Geocronología-UNAM.
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Caballero, M., Mora, L., Muñoz, E. et al. Anthropogenic influence on the sediment chemistry and diatom assemblages of Balamtetik Lake, Chiapas, Mexico. Environ Sci Pollut Res 27, 15935–15943 (2020). https://doi.org/10.1007/s11356-019-04581-9
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DOI: https://doi.org/10.1007/s11356-019-04581-9