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The recording of floods and earthquakes in Lake Chichój, Guatemala during the twentieth century

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Abstract

Laguna Chichój (Lake Chichój) is the only deep permanent lake in the central highlands of Guatemala. The lake is located in the boundary zone between the North American and Caribbean plates. The lake has been struck by devastating earthquakes and tropical cyclones in historical times. We investigated the imprint of twentieth century extreme events on the sedimentary record of this tropical lake using a bathymetric survey of the lake, coring the lake floor, and providing a chronology of sediment accumulation. The lake occupies a series of circular depressions likely formed by the rapid dissolution of a buried body of gypsum. 210Pb and 137Cs inventories and varve counting indicate high rates of sedimentation (1–2 cm year−1). The annually layered sediment is interrupted by turbidites of two types: a darker-colored turbidite, enriched in lake-derived biogenic constituents, and interpreted as a seismite, and a lighter-colored type, enriched in catchment-derived constituents, interpreted as a flood layer. Comparison of our 137Cs-determined layer ages with a catalog of twentieth century earthquakes shows that an earthquake on the Motagua fault in 1976 generated a conspicuous darker-colored turbidite and slumped deposits in separate parts of the lake. The entire earthquake inventory further reveals that mass movements in the lake are triggered at Modified Mercalli Intensities higher than V. Tropical cyclonic depressions known to have affected the lake area had limited effect on the lake, including Hurricane Mitch in 1998. One storm however produced a significantly thicker flood layer in the 1940s. This storm is reportedly the only event to have generated widespread slope failures in the lake catchment. It is thus inferred that abundant landsliding provided large amounts of concentrated sediment to the lake, through hyperpycnal flows.

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References

  • Adatte T, Stinnesbeck W, Keller G (1996) Lithostratigraphic and mineralogic correlations of near K/T boundary clastic sediments in northeastern Mexico: implication for origin and nature of deposition. Geol Soc Am Spec Publ 307:211–226

    Google Scholar 

  • Alpizurez-Palma JR (1978) Estudio ecológico de la Laguna Chichój. Engineering Master’s thesis, University of San Carlos de Guatemala

  • Alvarez-Rangel N (1995) Análisis multielemental por reflexión total de rayos X, en tejido muscular de lobina Micropterus salmoides (lacepade) y guapote Cichlasoma maneguense (Gunter), en la laguna de Chichój, San Cristóbal Verapaz. Biology engineering Master’s thesis, University San Carlos de Guatemala

  • Anselmetti FS, Ariztegui D, Brenner M, Hodell D, Rosenmeier MF (2007) Quantification of soil erosion rates related to ancient Maya deforestation. Geology 35:915–918

    Article  Google Scholar 

  • Arce-Canahui A (1992) Caracterización biofísica y socioeconómica de la cuenca de la Laguna Chichój. Univ San Carlos Guatemala, Dirección General de Investigación

  • Arnaud F, Lignier V, Revel M, Desmet M, Beck C, Pourchet M, Charlet F, Trentesaux A, Tribovillard N (2002) Flood and earthquake disturbance of 210Pb geochronology (Lake Anterne, NW Alps). Terra Nova 14:225–232

    Article  Google Scholar 

  • Authemayou C, Brocard G, Teyssier C, Suski B, Cosenza-Muralles B, Morán-Ical S, González-Véliz CW, Aguilar-Hengstenberg M-A, Holliger K (2012) Quaternary seismo-tectonic activity of the Polochic Fault, Guatemala. J Geophys Res 117:B07403. doi:10.1029/2012JB009444

    Google Scholar 

  • Bettini A (2011) Anthropisation du lac Chichój, San Cristóbal Verapaz, Guatémala. Master’s thesis, Université de Lausanne, Switzerland

  • Binford MW, Brenner M, Leyden BW, Whitmore TJ, Higuera-Diaz A, Deevey ES (1987) Ecosystems, paleoecology, and human disturbance in subtropical and tropical America. Quat Sci Rev 6:115–128

    Article  Google Scholar 

  • Blott SJ, Pye K (2001) Gradistat: a grain size distribution and statistics package for the analysis of unconsolidated sediments. Earth Surf Proc Land 26:1237–1248

    Article  Google Scholar 

  • Brezonik PL, Fox JL (1974) The limnology of selected Guatemalan Lakes. Hydrobiologia 45:467–487

    Article  Google Scholar 

  • Bucknam RC, Coe JA, Mota-Chavarría M, Godt JW, Tarr AC, Bradley L-A, Rafferty S, Hancock D, Dart RL, Johnson ML (2001) Landslides triggered by Hurricane Mitch in Guatemala—inventory and discussion. US Geol Surv Open-File Report 01-443

  • Drexler WJ, Rose WL, Sparks RSJ, Ledbetter MT (1980) The Los Chocoyos Ash, Guatemala: a major stratigraphic marker in Middle America and in three ocean basins. Quat Res 13:327–345

    Article  Google Scholar 

  • Espinoza AF, Husid R, Quesada A (1976) Intensity distribution and source parameters from field observations. In: Espinoza AF (ed) The Guatemalan Earthquake of February 4, 1976, a preliminary report. US Geol Surv Prof Paper 1002, 52–62

  • Friedel MJ (2008) Tegularized joint inverse estimation of extreme rainfall amounts in ungauged coastal basins of El Salvador. Nat Hazards 46:15–34

    Article  Google Scholar 

  • Gage T (1648) New survey of the West Indies, or the English-American his travel by sea and land. A. Clark, London, 1677

  • Gilli A, Anselmetti FS, Glur L, Wirth SB (2013) Lake sediments as archives of recurrence rates and intensities of past flood events. In: Schneuwly-Bollschweiler M, Stoffel M, Rudolf-Miklau F (eds) Dating torrential processes on fans and cones—methods and their application for hazard and risk assessment. Adv Glob Change Res 47:225–242

  • Goldberg ED (1963) Geochronology with 210Pb. Radioactive dating, 7 Int Atomic Energy Agency: 121–131

  • Goldfinger C (2011) Submarine paleoseismology based on turbidite records. Ann Rev Marine Sci 3:35–66

    Article  Google Scholar 

  • Guerra-Noriega A (2010) Climate-related disaster risk in mountain areas: the Guatemalan Highlands at the start of the 21st century. PhD, University of Oxford, Oxford, UK

  • Harp EL, Wilson RC, Wieczorek GF (1981) Landslides from the February 4, 1976, Guatemala earthquake. US Geol Surv Prof Paper 1024-A

  • Hernandez-Suarez FJ, El-Daoushy F (2002) Semi-empirical method for the self-absorption correction of photons with energies as low as 10 keV in environmental samples. Nucl Instrum Methods Phys 484:625–641

    Article  Google Scholar 

  • Hibsch C, Alvarado A, Yepes H, Perez VH, Sébrier M (1997) Holocene liquefaction and soft-sediment deformation in Quito (Ecuador): a paleoseismic history recorded in lacustrine sediments. J Geodyn 24:259–280

    Article  Google Scholar 

  • INDE (1974) Pueblo Viejo Project Feasibility Study. Instituto Nacional de Electrificación, Guatemala

    Google Scholar 

  • INSIVUMEH—Instituto Nacional de Sismologia, Vulcanologia, Meteorologia y Hidrologia. http://www.insivumeh.gob.gt

  • Krishnaswami D, Lal JM, Martin M, Meybeck M (1971) Geochronology of lake sediments. Earth Planet Sci Lett 11:407–414

    Article  Google Scholar 

  • Kübler B (1983) Dosage quantitatif des minéraux majeurs des roches sédimentaires par diffraction X. Cahier de l’Institut de Géologie de Neuchâtel, Switzerland, ADX 1.1–1.2

  • Kübler B (1987) Cristallinité de l’illite, méthodes normalisées de préparations, méthodes normalisées de mesures. Cahier de l’Institut de Géologie de Neuchâtel, Switzerland, ADX. 1.3

  • Larsen MC, Simon A (1993) A rainfall intensity-duration threshold for landslides in a humid-tropical environment, Puerto Rico. Geografiska Annnaler 75A:13–23

    Article  Google Scholar 

  • Lauterbach S, Chapron E, Brauer A, Hüls MM, Gilli A, Araud F, Piccin A, Nomade J, Desmet M, von Grafensteiun U (2012) DecLakes participants (2012) a sedimentary record of Holocene surface runoff events and earthquake activity from Lake Iseo (Southern Alps, Italy). The Holocene 22:749–760

    Article  Google Scholar 

  • Lopez F (1999) Evaluación Hidrológia de las Crecidas Provocadas por el Paso del Huracán Mitch en Guatemala. PHI/UNESCO, Montevideo

    Google Scholar 

  • Lyon-Caen H, Barrier E, Lasserre C, Franco H, Arzú I, Chiquín L, Chiquín M, Dusquesnoy T, Flores O, Galicia O, Luna J, Molina E, Porras O, Requena J, Robles V, Romero J, Wolf R (2006) Kinematics of the North American-Caribbean-Cocos plates in Central America from new GPS measurements across the Polochic-Motagua fault system. Geophys Res Let 33:L19309. doi:10.1029/2006GL027694

    Article  Google Scholar 

  • Malaizé B, Bertran P, Carbonel P, Bonnissent D, Charlier K, Galop D, Imbert D, Serrand N, Stouvenot C, Pujol C (2011) Hurricanes and climate in the Caribbean during the past 3700 years BP. Holocene 21:911–924

    Article  Google Scholar 

  • Mijangos N (2000) Caracterización y diagnóstico de la calidad de agua de las fuentes contaminantes de la cuenca y de la Laguna Chichój, San Cristóbal, Verapaz y Alta Verapaz. Fondo Guatemalteco del Medio Ambiente, Guatemala

    Google Scholar 

  • Monecke K, Anselmetti FS, Becker A, Sturm M, Giardini D (2004) The record of historic earthquakes in lake sediments of Central Switzerland. Tectonophysics 394:21–40

    Article  Google Scholar 

  • Mouriño C, Basterrechea M, Molina S, De Zepeda M, De Juárez Y, Aguilar E, Oliva B, Castellanos P, Palacios R, Palma J (1994) Calidad de agua y nivel trófico de la laguna Chichój, Alta Verapaz, Guatemala. Guatemala, Dirección de Energía Nuclear de Guatemala, Ciencia y Tecnología Nuclear 1:32–42

  • Mulder T, Cochonat P (1996) Classification of offshore mass movements. J Sediment Res 66(1):43–57

    Google Scholar 

  • Mulder T, Syvitski JPM, Migeon S, Faugères J-C, Savoye B (2003) Marine hyperpycnal flows: initiation, behavior and related deposits. A review. Mar Petrol Geol 20:861–882

    Article  Google Scholar 

  • Musk LF (1988) Weather systems. Cambridge University Press, Cambridge

    Google Scholar 

  • Newhall CG, Paull KC, Bradbury JP, Higuera-Gundy A, Poppe LJ, Self S, Bonar Sharpless N, Ziagos J (1987) Recent geologic history of Lake Atitlán, a caldera lake in western Guatemala. J Volcanol Geothermal Res 33:81–107

    Article  Google Scholar 

  • NOAA (National Oceanic and Atmospheric Administration), Historical Hurricane Tracks. http://maps.csc.noaa.gov/hurricanes/#

  • Noller JS (2000) Lead-210 geochronology. In: Noller JS (ed) Quaternary geochronology methods and applications. American Geophysical Union, Washington, AGU Reference Shelf 4:115–120

  • Plafker G (1976) Tectonic aspects of the Guatemala earthquake of 4th February 1976. Science 93:1201–1208

    Article  Google Scholar 

  • Poppe LJ, Paull CK, Newhall CG, Bradburz JP, Ziagos J (1985) A geophysical and geological study of Laguna de Ayarza, a Guatemalan caldera lake. J Volcanol Geothermal Res 25:125–144

    Article  Google Scholar 

  • Rose WI, Newhall CG, Bornhorst TJ, Self S (1986) Quaternary silicic pyroclastic deposits of Atitlán caldera, Guatemala. In Williams SN Carr MJ (eds) Stoiber RE 75th birthsday volume. J Volcanol Geothermal Res 33:57–80

  • Schnellmann M, Anselmetti FS, Giardini D, McKenzie JA, Ward S (2002) Prehistoric earthquake history revealed by lacustrine slump deposits. Geology 3:1131–1134

    Article  Google Scholar 

  • Strasser M, Anselmetti FS, Fäh D, Giardini D, Schnellmann M (2006) Magnitudes and source areas of large prehistoric northern Alpine earthquakes revealed by slope failures in lakes. Geology 34:1005–1008

    Article  Google Scholar 

  • Suski B, Brocard G, Authemayou C, Consenza-Muralles B, Teyssier C, Holliger K (2010) Localization and characterization of an active fault in an urbanized area in central Guatemala by the means of geoelectrical imaging. Tectonophysics 480:88–98

    Article  Google Scholar 

  • Swierczynski T, Brauer A, Lauterbach S, Martín-Puertas C, Dulski P, von Grafenstein U, Rohr C (2012) A 1600 yr seasonally resolved record of decadal-scale flood variability from the Austrian Pre-Alps. Geology 40:1047–1050

    Article  Google Scholar 

  • Terga R (1979) Caccoh, Donde Brota el Mar Pequeño. Instituto Indígena Nacional, Guatemala: Guatemala Indígena 14

  • Viana F, Gallego L, Cadena G (1955) Relación de la provincia de la Verapaz, hecha por los religiosos de Santo Domingo de Cobán, Guatemala (1574). An Soc Geog Hist Guatemala 28:18–31

    Google Scholar 

  • White RA (1984) Catalog of historic seismicity in the vicinity of the Chixóy-Polochic and Motagua faults, Guatemala. US Geol Surv open-file report, 84–88

  • White RA, Harlow DH (1993) Destructive upper-crustal earthquakes of Central America since 1900. Bull Seismol Soc Am 83:115–1142

    Google Scholar 

  • White RA, Ligorria JP, Cifuentes IL (2004) Seismic history of the Middle America subduction zone along El Salvador, Guatemala, and Chiapas, Mexico: 1526–2000. In: Rose WI, Bommer JJ, López DL, Carr MJ, Major JJ (eds), Natural hazards in El Salvador. Geol Soc Am Spec Paper 375:379–396

  • Wilhelm B, Arnaud F, Enters D, Allignol F, Legaz A, Magand O, Revillon S, Giguet-Covex C (2012) Does global warming favour the occurrence of extreme floods in European Alps? First evidences from a NW Alps progracial lake sediment record. Climate Change. doi:10.1007/s10584-011-0376-2

  • Wirth SF, Girardclos S, Rellstab C, Anselmetti F (2011) The sedimentary response to a pioneer geo-engineering project: tracking the Kander River deviation in the sediments of Lake Thun (Switzerland). Sedimentology 58:1737–1761

    Article  Google Scholar 

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Acknowledgments

This work was supported by Swiss National Science Foundation Grants 200021-112175/1 and 200020-120117/1. We thank Alois Zwyssig at the Swiss Federal Institute of Aquatic Science and Technology (Eawag), and Céline Pignol at the Edytem, University of Savoie, France, for their technical support during core opening. We thank two anonymous reviewers for their thorough review that significantly improved the manuscript.

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Correspondence to Gilles Brocard.

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Brocard, G., Adatte, T., Magand, O. et al. The recording of floods and earthquakes in Lake Chichój, Guatemala during the twentieth century. J Paleolimnol 52, 155–169 (2014). https://doi.org/10.1007/s10933-014-9784-4

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