Effects of drought and subtidal sea-level variability on salt intrusion in a coastal karst aquifer

Article

<< Previous

Next >>

Contents Vol 63(6)

doi:10.1071/MF11270

Advances in the Aquatic Sciences

	Search




	Advanced Search



	Journal Home

	About the Journal

	Editorial Board

	Contacts



	Content

	Online Early

	Current Issue

	Just Accepted

	All Issues

	Special Issues

	Sample Issue



	For Authors

	General Information

	Instructions to Authors

	Submit Article

	Open Access



	For Referees

	General Information

	Review Article

	Referee Guidelines

	Early Career Referee Mentoring



	For Subscribers

	Subscription Prices

	Customer Service

	Print Publication Dates

e-Alerts

Subscribe to our Email Alert or

feeds for the latest journal papers.

Connect with us

Effects of drought and subtidal sea-level variability on salt intrusion in a coastal karst aquifer

Irany Vera ^A ^B, Ismael Mariño-Tapia ^A ^B and Cecilia Enriquez ^A

^A Centro de Investigación y Estudios Avanzados del Instituto Politécnico Nacional, km 6 Antigua Carretera a Progreso, C.P. 97310, (999)9429458, Mérida, México.
^B Corresponding authors. Email: ivera@mda.cinvestav.mx; imarino@mda.cinvestav.mx

Marine and Freshwater Research 63(6) 485-493 http://dx.doi.org/10.1071/MF11270
Submitted: 8 December 2011 Accepted: 4 March 2012 Published: 9 May 2012





	PDF (626 KB) $25



	Export Citation

Print

Abstract

In many coastal regions, groundwater is the main water source for humans. However, because of population growth and sea-level rise, many coastal aquifers increasingly suffer from salt intrusion, especially in karstic areas where the high permeability and porosity of the rock favours salt penetration. We collected field data from a Mexican karst system to show that sea-level variability at low frequencies (subtidal) may induce salt penetration further inland and generate larger oscillations than those observed at tidal frequencies. Measurements of conductivity and pressure from inland wells (5 and 10 km) and from substantial (~1 m³ s^–1) submarine groundwater discharge (SGD) at ~2-m depth entering a shallow ocean were analysed. We found that sea and piezometric levels co-oscillated at subtidal frequencies, with a correlation of 0.6 and a differential lag. Conductivity of the SGD resembled that of the aquifer. Intense droughts driven by the 2009 ‘El Niño’ event markedly increased the conductivity of the aquifer and its discharge. Our findings indicated that coastal land use and the consequences of climate change (i.e. sea-level rise and the alteration of rain patterns) on the Yucatan Penisula threaten water availability.

Additional keywords: climate change, frequency-dependent intrusion, seasonal variability, submarine springs, Yucatan.

References

Anderson, W. P., and Emanuel, R. (2010). Effect of interannual climate oscillations on rates of submarine groundwater discharge. Water Resources Research 46, W05503.
| CrossRef |

Back, W., and Lesser, J. M. (1981). Chemical constraints of groundwater management in the Yucatan Peninsula, Mexico. Journal of Hydrology (Amsterdam) 51, 119–130.
| CrossRef |

Bauer-Gottwein, P., Gondwe, R. N., Charvet, G., Marin, L. E., Rebolledo-Vieyra, M., and Merediz- Alonso, G. (2011). Review: the Yucatán Peninsula karst aquifer, Mexico. Hydrogeology Journal 19, 507–524.
| CrossRef |

Beddows, P. A. (2004). Groundwater hydrology of a coastal conduit carbonate aquifer: Caribbean coast of the Yucatán Peninsula, México. Ph.D. Thesis, University of Bristol, UK.

Calaforra, J. M., Ballarin, L., Ginés, J., Perleros, V., and Tiniakos, L. (2005). A classification of the coastal karst aquifers of the Mediterranen Sea. In ‘COST-621 Action: Groundwater Management of Coastal Karstic Aquifers’. (Eds L. Tulipano, M. D. Fidelibus and A. Panagopoulos.) pp. 23–45. (COST Office: Luxembourg.)

Capurro-Filograsso, L., and Reid, J. L. (1972). ‘Contribution on the Physical Oceanography of the Gulf of Mexico.’ (Gulf Publishing: Houston, TX.)

Comisión Nacional del Agua (2011). ‘Estadísticas del Agua en México.’ (Secretaria de Medio Ambiente y Recursos Naturales: México.)

Emery, W. J., and Thomson, R. E. (2001). ‘Data Analysis Methods in Physical Oceanography.’ 2nd edn. (Elsevier B.V.: Amsterdam, The Netherlands.)

Enriquez, C., Mariño-Tapia, I., and Herrera-Silveira, J. (2010). Dispersion in the Yucatan coastal zone: implications for red tide events. Continental Shelf Research 30, 127–137.
| CrossRef |

Ferris, J. G. (1951). Cyclic fluctuation of water level as a basis for determining aquifer transmissibility. International Association of Scientific Hydrology 33, 148–155.

Fleury, P., Bakalowicz, M., and de Marsily, G. (2007). Submarine springs and coastal karst aquifers: a review. Journal of Hydrology 339, 79–92.
| CrossRef |

Marín, L. E., Steinich, B., Pacheco, J., and Escolero, O. A. (2000). Hydrogeology of contaminated sole-source karst aquifer, Merida, Yucatan, Mexico. Geofísica Internacional 39, 359–365.

Michael, H. A., Mulligan, A. E., and Harvey, C. F. (2005). Seasonal oscillations in water exchange between aquifers and the coastal ocean. Nature 436, 1145–1148.
| CrossRef | CAS |

Moore, W. (2010). The effect of submarine groundwater discharge on the ocean. Annual Review of Materials Science 2, 59–88.
| CrossRef |

Perry, E. C., Swift, J., Gamboa, J., Reeve, A., Sanborn, R., Marín, L., and Villasuso, M. (1989). Environmental aspects of surface cementation, north coast, Yucatan, Mexico. Geology 17, 818–821.
| CrossRef | CAS |

Peterson, R. N., Burnett, W. C., Glenn, C. R., and Johnson, A. G. (2009). Quantification of point-source groundwater discharges to the ocean from the shoreline of the Big Island, Hawaii. Limnology and Oceanography 54, 890–904.
| CrossRef |

Robinson, C., Li, L., and Prommer, H. (2007). Tide induced recirculation across the aquifer-ocean interface. Water Resources Research 43, W07428.
| CrossRef |

Santos, I. R., Burnett, W. C., Chanton, J., Dimova, N., and Peterson, R. N. (2009). Land or ocean? Assessing the driving forces of submarine groundwater discharge at a coastal site in the Gulf of Mexico. Journal of Geophysical Research 114, C04012.
| CrossRef |

Smith, C. G., Cable, J. E., and Martin, J. B. (2008). Episodic high intensity mixing events in a subterranean estuary: effects of tropical cyclones. Limnology and Oceanography 53, 666–674.
| CrossRef |

Taniguchi, M. (2002). Tidal effects on submarine groundwater discharge into the ocean. Geophysical Research Letters 29, 1561.
| CrossRef |

Valle-Levinson, A., Mariño, I., Enriquez, C., and Waterhouse, A. (2011). Tidal variability of salinity and velocity fields related to intense point-source submarine groundwater discharges into the coastal ocean. Limnology and Oceanography 56, 1213–1224.
| CrossRef |

Welch, P. D. (1967). The use of fast fourier transform for the estimation of power spectra: a method based on time averaging over short, modified periodograms. IEEE Transactions on Audio and Electroacoustics 15, 70–73.
| CrossRef |

Xin, P., Robinson, C., Li, L., Barry, D. A., and Bakhytar, R. (2010). Effects of wave forcing on a subterranean estuary. Water Resources Research 46, W12505.
| CrossRef |

Zavala-Hidalgo, J., Morey, S. L., and O’Brien, J. J. (2003). Seasonal circulation on the western shelf of the Gulf of Mexico using a high-resolution numerical model. Geophysical Research 108, 3389.
| CrossRef |

Subscriber Login

	Username: Password:

Legal & Privacy | Contact Us | Help