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Hydrogeology Journal

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06-07-2019 | Report

Sequential indicator simulation for a three-dimensional distribution of hydrofacies in a volcano-sedimentary aquifer in Mexico City

Authors: Priscila Medina-Ortega, Eric Morales-Casique, Antonio Hernández-Espriú

Published in: Hydrogeology Journal | Issue 7/2019

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Abstract

The Mexico City aquifer is a complex mix of alluvial deposits and volcanic rocks overlapped by an aquitard composed of lacustrine deposits. To characterize this heterogeneous hydrogeologic system, a three-dimensional model of the distribution of hydrofacies is constructed using borehole lithological records. The analysis is based on 111 borehole logs with an average depth of 300 m, in an area of 234 km², providing a nominal scale of resolution of 2.1 km in the plane and 2-m resolution in the vertical direction. These records were discretized to generate a georeferenced dataset of 13,518 points associated with a lithological category; nine lithological categories were observed. These categories were subsequently grouped into four hydrofacies: A and B, grouping low-permeability lithological categories (lacustrine and volcano-sedimentary materials, respectively); and C and D, grouping high-permeability lithological categories (volcanic rocks and alluvial deposits, respectively). The database was analyzed in terms of proportion of hydrofacies at depth, distribution of layer thickness, and behavior of experimental horizontal and vertical variograms. The experimental variograms of each hydrofacies were fitted to exponential models via minimization of cross-validation errors. Three-dimensional models of probability of occurrence of each hydrofacies and the combined distribution of hydrofacies were then constructed via ensemble averaging of 1,000 realizations obtained by sequential indicator simulation. The potential use of this model for water management, modeling land subsidence, and groundwater pollution is discussed.

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Arce JL, Layer PW, Morales-Casique E, Benowitz JA, Rangel E, Escolero OA (2013) New constraints on the subsurface geology of the Mexico City Basin: the San Lorenzo Tezonco deep well, on the basis of 40Ar/39Ar geochronology and whole-rock chemistry. J Volcanol Geothermal Res 266:34–49. https://doi.org/10.1016/j.jvolgeores.2013.09.004. CrossRef

Arce JL, Layer PW, Martínez I, Salinas JI, Macías-Romo MC, Morales-Casique E, Benowitz JA, Escolero O, Lenhardt N (2015) Geología y estratigrafía del pozo profundo San Lorenzo Tezonco y de sus alrededores, sur de la Cuenca de México [Geology and stratigraphy of the San Lorenzo Tezonco deep well and its surroundings, south of the Basin of Mexico]. Bol Soc Geol Mexicana 67(2):123–143.

Arce JL, Layer PW, Macías JL, Morales-Casique E, García-Palomo A, Jiménez-Domínguez FJ, Benowitz J, Vásquez-Serrano A (2019) Geology and stratigraphy of the Mexico Basin (Mexico City), central Trans-Mexican Volcanic Belt. J Maps 15(2):320–332. https://doi.org/10.1080/17445647.2019.1593251

Arroyo D, Ordaz M, Ovando-Shelley O, Guasch JC, Lermo J, Perez C, Alcantara L, Ramírez-Centeno MS (2013) Evaluation of the change in dominant periods in the lake-bed zone of Mexico City produced by ground subsidence through the use of site amplification factors. Soil Dynam Earthquake Eng 44:54–66. https://doi.org/10.1016/j.soildyn.2012.08.009 CrossRef

Auvinet G (2009) Land subsidence in Mexico City. In: Auvinet GY, Juárez M (eds) Geotechnical engineering in urban areas affected by land subsidence. Volume prepared by ISSMGE Technical Committee 36 for XVII ISSMGE Conference, Alexandria, Egypt, vol 2009. Mexican Society of Soil Mechanics, Mexico City, pp 3–11

Avilés J, Pérez-Rocha LE (2010) Regional subsidence of Mexico City and its effects on seismic response. Soil Dynam Earthquake Eng 30(10):981–989. https://doi.org/10.1016/j.soildyn.2010.04.009 CrossRef

Cabral-Cano E, Dixon TH, Miralles-Wilhelm F, Díaz-Molina O, Sánchez-Zamora O, Carande RE (2008) Space geodetic imaging of rapid ground subsidence in Mexico City. GSA Bull 120(11–12):1556–1566. https://doi.org/10.1130/B26001.1 CrossRef

Carle SF, Fogg GE (1996) Transition probability-based indicator geostatistics. Mathematic Geol 28(4):453–476CrossRef

Carle SF, Fogg GE (1997) Modeling spatial variability with one and multidimensional continuous-lag Markov chain. Mathemat Geol 29(7):891–918CrossRef

Carreón-Freyre D, Cerca M, Gutiérrez-Calderón R, Huerta-Ladrón De Guevara M (2010) Monitoring of land subsidence and fracturing in Iztapalapa, Mexico City, In: Carreón-Freyre D, Cerca M, Galloway DL (eds) Land subsidence: associated hazards and the role of natural resources development. IAHS Publ. 339, IAHS, Wallingford, UK, pp 44–50

Carreón-Freyre D, González-Hernández M, Cerca M, Gutiérrez-Calderón R, Jiménez Sánchez CA (2011) Caracterización geomecánica de los suelos de Iztapalapa, México, para evaluar el fracturamiento causado por deformación diferencial [Geomechanical characterization of soils in Iztapalapa, México, to evaluate fracturing caused by differential deformation]. In: Conference Proceedings 2011 Pan-Am CGS Geotechnical Conference, Canadian Geotechnical Society, Richmond, BC, pp 1599–1606

Carrera-Hernández JJ, Gaskin SJ (2008) Spatio-temporal analysis of potential aquifer recharge: application to the Basin of Mexico. J Hydrol 353:228–246. https://doi.org/10.1016/j.jhydrol.2008.02.012 CrossRef

dell’Arciprete D, Bersezio R, Felletti F, Giudici M, Comunian A, Renard P (2012) Comparison of three geostatistical methods for hydrofacies simulation: a test on alluvial sediments. Hydrogeol J 20(2):299–311. https://doi.org/10.1007/s10040-011-0808-0 CrossRef

Deutsch CV, Journel AG (1998) GSLIB geostatistical software library and user’s guide, 2nd edn. Oxford University Press, New York

Doherty J (2010) PEST, Model-independent parameter estimation: user manual, 5th edn. Watermark, Brisbane, Australia

Domínguez-Mariani E, Vargas-Cabrera C, Martínez-Mijangos F, Gómez-Reyes E, Monroy-Hermosillo O (2015) Determinación de los procesos hidrogeoquímicos participantes en la composición del agua de las fuentes de abastecimiento a pobladores de la delegación Iztapalapa, D.F., México [Determination of hydrogeochemical processes associated with the composition of water from supply wells for the inhabitants of the Iztapalapa District, D.F., Mexico]. Bol Soc Geol Mexicana 67(2):299–313. https://doi.org/10.18268/BSGM2015v67n2a12 CrossRef

Escolero O, Kralisch S, Martínez SE, Perevochtchikova M (2016) Diagnóstico y análisis de los factores que influyen en la vulnerabilidad de las fuentes de abastecimiento de agua potable a la Ciudad de México, México [Diagnosis and analysis of factors that affect the vulnerability of potable water supply sources to Mexico City, Mexico]. Bol Soc Geol Mexicana 68(3):409–427CrossRef

Ezzedine S, Rubin Y, Chen J (1999) Bayesian method for hydrogeological site characterization using borehole and geophysical survey data: theory and application to the Lawrence Livermore National Laboratory Superfund Site. Water Resour Res 35(9):2671–2683CrossRef

Fogg GE, Noyes CD, Carle SF (1998) Geologically based model of heterogeneous hydraulic conductivity in an alluvial setting. Hydrogeol J 6(1):131–143CrossRef

Freeze RA, Massmann J, Smith L, Sperling T, James B (1990) Hydrogeological decision-analysis 1: a framework. Ground Water 28(5):738–766. https://doi.org/10.1111/j.1745-6584.1990.tb01989.x CrossRef

García-Palomo A, Zamorano JJ, López-Miguel C, Galván-García A, Carlos-Valerio V, Ortega R, Macías JL (2008) El arreglo morfoestructural de la Sierra de Las Cruces, México central [The morphostructural arrangement of the Sierra de Las Cruces, central Mexico]. Rev Mexicana Cien Geol 25(1):158–178

He X, Koch J, Sonnenborg TO, Jørgensen F, Schamper C, Refsgaard JC (2014) Transition probability-based stochastic geological modeling using airborne geophysical data and borehole data. Water Resour Res 50. https://doi.org/10.1002/2013WR014593

Hernández-Espriú A, Reyna-Gutiérrez JA, Sánchez-León E, Cabral-Cano E, Carrera-Hernández J, Martínez-Santos P, Macías-Medrano S, Falorni G, Colombo D (2014) The DRASTIC-Sg model: an extension to the DRASTIC approach for mapping groundwater vulnerability in aquifers subject to differential land subsidence, with application to Mexico City. Hydrogeol J 22(6):1469–1485. https://doi.org/10.1007/s10040-014-1130-4 CrossRef

Instituto de Geofísica-UNAM (1994) Diagnóstico del estado presente de las aguas subterráneas de la Ciudad de México y determinación de sus condiciones futuras [Diagnosis of the current state of groundwater in Mexico City and determination of its future conditions]. Technical report for Departamento del Distrito Federal, Dirección General de Construcción y Operación Hidráulica, Mexico City, 110 pp

Jaime-P A, Méndez-Sánchez E (2010) Evolution of Mexico City clay properties affected by land subsidence. In: Carreón-Freyre D, Cerca M, Galloway DL, Silva-Corona JJ (eds) Land subsidence, associated hazards and the role of natural resources development. IAHS Publ. 339, IAHS, Wallingford, UK, pp 232–234

Johnson NM (1995) Characterization of alluvial hydrostratigraphy with indicator semivariograms. Water Resour Res 31(12):3217–3227CrossRef

Johnson NM, Dreis SJ (1989) Hydrostratigraphic interpretation using indicator geostatistics. Water Resour Res 25(12):2501–2510CrossRef

Jørgensen F, Høyera AS, Sandersen PBE, He X, Foged N (2015) Combining 3D geological modelling techniques to address variations in geology, data type and density: an example from southern Denmark. Comput Geosci 81:53–63. https://doi.org/10.1016/j.cageo.2015.04.010 CrossRef

Journel AG (1983) Nonparametric estimation of spatial distributions. Math Geol 15(3):445–468CrossRef

Lozano-García S, Brown ET, Ortega B, Caballero M, Werne J, Fawcett PJ, Schwalb A, Valero-Garcés BL, Schnurrenberger D, O’Grady R, Stockhecke M, Steinman B, Cabral-Cano E, Caballero C, Sosa-Nájera S, Soler AM, Pérez L, Noren A, Myrbo A, Bücker M, Wattrus N, Arciniega A, Wonik T, Watt S, Kumar D, Acosta C, Martínez I, Cossio R, Ferland T, Vergara-Huerta F (2017) Perforación profunda en el lago de Chalco: reporte técnico [Deep drilling at the Chalco lake: a technical report]. Bol Soc Geol Mexicana 69(2):299–311. https://doi.org/10.18268/BSGM2017v69n2a2

Marsal RJ, Mazari M (1959) The subsoil of Mexico City, vol 377. Universidad Nacional Autónoma de México, Mexico City

Medina-Ortega P (2016) Modelo geoestadístico de hidrofacies y parametrización hidrogeológica de una porción del acuífero aluvial de la Ciudad de México [Geostatistical model of hydrofacies and hydrogeologic parameterization of a portion of the alluvial aquifer of Mexico City]. MSc Thesis, Universidad Nacional Autónoma de México, Mexico, 227 pp

Montiel-Palma S, Armienta-Hernández MA, Rodríguez-Castillo R, Domínguez-Mariani E (2014) Identificación de zonas de contaminación por nitratos en el agua subterránea de la zona sur de la Cuenca de México [Identification of zones contaminated by nitrate in groundwater in the southern portion of the Basin of Mexico]. Rev Internacional de Contaminación Ambiental 30(2):149–165

Morales-Casique E, Escolero OA, Arce JL (2015) Estimación de parámetros mediante inversión y análisis de las pérdidas hidráulicas lineales y no-lineales durante el desarrollo y aforo del pozo San Lorenzo Tezonco [Estimation of parameters using inversion and analysis of linear and non-linear hydraulic losses during the development and step-drawdown testing of the San Lorenzo Tezonco well]. Bol Soc Geol Mexicana 67(2):203–214. https://doi.org/10.18268/BSGM2015v67n2a5 CrossRef

Mooser F (2018) Geología del Valle de México y otras regiones del país, vol I [Geology of the Valley of Mexico and other regions of the country, vol 1], 1st edn. Colegio de Ingenieros Civiles de México, Mexico City

Moysey S, Caers J, Knight R, Allen-King RM (2003) Stochastic estimation of facies using ground penetrating radar data. Stochast Environ Res Asses 17(5):306–318. https://doi.org/10.1007/s00477-003-0152-6 CrossRef

National Research Council (1995) Mexico City’s water supply: improving the outlook for sustainability. The National Academies Press, Washington, DC. https://doi.org/10.17226/4937

Ortega-Guerrero A, Rudolph DL, Cherry JA (1999) Analysis of long-term land subsidence near Mexico City: field investigations and predictive modeling. Water Resour Res 35(11):3327–3341

Ortega-Guerrero B, Lozano-García S, Herrera-Hernandez D, Caballero M, Beramendi-Orosco L, Bernal JP, Torres-Rodríguez E, Avendano-Villeda D (2017) Lithostratigraphy and physical properties of lacustrine sediments of the last ca. 150 kyr from Chalco basin, central Mexico. J South Am Earth Sci 79:507–524. https://doi.org/10.1016/j.jsames.2017.09.003 CrossRef

Ovando-Shelley E, Ossa A, Santoyo E (2013) Effects of regional subsidence and earthquakes on architectural monuments in Mexico City. Bol Soc Geol Mexicana 65(1):157–167CrossRef

Poeter E, Gaylord DR (1990) Influence of aquifer heterogeneity on contaminant transport at the Hanford Site. Ground Water 28(6):900–909. https://doi.org/10.1111/j.1745-6584.1990.tb01726.x CrossRef

Ritzi RW, Jayne DF, Zahradnik AJ, Field AA, Fogg GE (1994) Geostatistical modeling of heterogeneity in glaciofluvial, buried-valley aquifers. Ground Water 32(4):666–674. https://doi.org/10.1111/j.1745-6584.1994.tb00903.x CrossRef

Ritzi RW (2000) Behavior of indicator variograms and transition probabilities in relation to the variance in lengths of hydrofacies. Water Resour Res 36(11):3375–3381CrossRef

Ritzi RW, Dominic DF, Slesers AJ, Greer CB, Reboulet EC, Telford JA, Masters RW, Klohe CA, Bogle JL, Means BP (2000) Comparing statistical models of physical heterogeneity in buried-valley aquifers. Water Resour Res 36(11):3179–3192CrossRef

Tortajada C (2006) Water management in Mexico City metropolitan area. Water Resour Develop 22(2):353–376. https://doi.org/10.1080/07900620600671367 CrossRef

Valencia-Cruz, NI (2002) Geología y correlación litoestratigráfica del subsuelo de la porción sur sureste del Valle de México. Facultad de Ingeniería, Universidad Nacional Autónoma de México, Mexico City, 85 pp

Vargas C, Ortega-Guerrero A (2004) Fracture hydraulic conductivity in the Mexico City clayey aquitard: field piezometer rising-head tests. Hydrogeol J 12(3):336–344. https://doi.org/10.1007/s10040-003-0302-4 CrossRef

Vazquéz-Sanchéz E, Jaimes-Palomera R (1989) Geología de la Cuenca de México [Geology of the Basin of Mexico]. Geofís Int 28(2):133–190

Zapata-Norberto B, Morales-Casique E, Herrera GS (2018) Nonlinear consolidation in randomly heterogeneous highly compressible aquitards. Hydrogeol J 26(3):755–769. https://doi.org/10.1007/s10040-017-1698-6 CrossRef

Title: Sequential indicator simulation for a three-dimensional distribution of hydrofacies in a volcano-sedimentary aquifer in Mexico City
Authors: Priscila Medina-Ortega
Eric Morales-Casique
Antonio Hernández-Espriú
Publication date: 06-07-2019
Publisher: Springer Berlin Heidelberg
Published in: Hydrogeology Journal / Issue 7/2019
Print ISSN: 1431-2174
Electronic ISSN: 1435-0157
DOI: https://doi.org/10.1007/s10040-019-02011-1

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