Register      Login
Exploration Geophysics Exploration Geophysics Society
Journal of the Australian Society of Exploration Geophysicists
RESEARCH ARTICLE

Identification of leachate from livestock mortality burial using electrical resistivity and small-loop EM survey: case history

Sung-Ho Song 1 In-Ky Cho 2 3 Kwang-Jun Choi 1
+ Author Affiliations
- Author Affiliations

1 Rural Research Institute, Korea Rural Community Corporation, Ansan 425-170, Korea.

2 Department of Geophysics, Kangwon National University, Chuncheon 200-701, Korea.

3 Corresponding author. Email: choik@kangwon.ac.kr

Exploration Geophysics 46(4) 387-393 https://doi.org/10.1071/EG14111
Submitted: 11 November 2014  Accepted: 12 November 2014   Published: 5 January 2015
Originally submitted to KSEG 28 February 2013, accepted 23 October 2014  

Abstract

Leachate from livestock mortality burial is harmful to the soil and groundwater environment and adequate assessment approaches are necessary to manage burial sites. Among the methods used to detect leachate, geophysical surveys, including electrical resistivity and electromagnetic (EM) techniques, are used in many engineering approaches to environmental problems, such as identifying contaminant plumes and evaluating hydrogeological conditions. Electrical resistivity, with a small-loop EM survey, was used in this study as a reconnaissance technique to identify the burial shape and distribution of leachate from livestock mortality burial in five small separate zones. We conducted a multi-frequency small-loop EM survey using lattice nets and acquired apparent conductivity values along several parallel and perpendicular lines over a burial site. We also compared geophysical results to the geochemical analysis of samples from both a leachate collection well and a downstream observation well within the study area. Depth slices of apparent conductivities at each frequency (obtained from the small-loop EM survey data) clearly identified the subsurface structure of the burial shape and the extent of leachate transport. Low-resistivity zones, identified from two-dimensional (2D) electrical resistivity imaging results, were matched to the five burial zones (within a depth of 5 m), as well as high electrical conductivity of the leachate obtained from leachate collection wells, and depth slices of the apparent conductivity distribution obtained from the small-loop EM survey. A three-dimensional (3D) inversion of resistivity data provided a detailed 3D structure of the overall burial site and leachate pathways. Moreover, these zones were widely spread over the burial site, indicating that leachate potentially extended through damaged regions of the composite liner to a depth of 10 m along the downstream groundwater flow. Both the small-loop EM method and the electrical resistivity method were considered suitable for identifying the shape of the livestock mortality burial and the extent of leachate.

Key words: electrical resistivity imaging, geochemical analysis, leachate, livestock mortality burial, small-loop electromagnetic survey.


References

Bastianon, D., Matos, B. A., Aquino, W. F., Pacheco, A., and Mendes, J. M. B., 2000, Geophysical surveying to investigate groundwater contamination by a cemetery: Proceedings of the Symposium on the Application of Geophysics to Engineering and Environmental Problems, The Annual Meeting of the Environmental and Engineering Geophysical Society, 709–718.

Caputo, M. C., Carlo, L. D., Cassiani, G., and Deiana, R., 2011, Electrical methods for monitoring a site potentially contaminated by landfill leachate: European Geosciences Union (EGU) General Assembly 2011, Vienna, 3–8 April 2011.

CAST, 2008, Poultry carcass disposal options for routine and catastrophic mortality: Council for Agricultural Science and Technology, Iowa, USA.

Freedman, R., and Fleming, R., 2003, Water quality impacts of burying livestock mortalities: Paper presented to the Livestock Mortality Recycling Project Steering Committee, Ridgetown College, University of Guelph, Canada.

Huang, H., and Won, I. J., 2000, Conductivity and susceptibility mapping using broadband electromagnetic sensors: Journal of Environmental & Engineering Geophysics, 5, 31–41
Conductivity and susceptibility mapping using broadband electromagnetic sensors:Crossref | GoogleScholarGoogle Scholar |

Huang, H., and Won, I. J., 2003, Real time resistivity sounding using a hand-held broadband electromagnetic sensor: Geophysics, 68, 1224–1231
Real time resistivity sounding using a hand-held broadband electromagnetic sensor:Crossref | GoogleScholarGoogle Scholar |

Kim, J. H., Hyun, B. K., and Chung, S. H., 1989, Automatic two-dimensional inversion of dipole-dipole resistivity data: Journal of the Korean Institute of Mineral and Mining Engineers, 26, 115–125

Kim, J. H., Yi, M. J., Song, Y., and Chung, S. H., 2001, A study on the modified electrode arrays in two-dimensional resistivity survey: Geophysics and Geophysical Exploration, 4, 59–69

Klefstad, G., Sendlein, L. V. A., and Palmquist, R. C., 1975, Limitations of the electrical resistivity method in landfill investigations: Ground Water, 13, 418–427
| 1:CAS:528:DyaE1cXnvVyruw%3D%3D&md5=9917ec12ab124b41166eb38f35734943CAS |

KMIFAFF (Korea Ministry for Food, Agricultural, Forestry and Fisheries), 2011, Manual for livestock mortality burial.

KMOE (Korea Ministry of Environment), 2010, Manual of environmental management for livestock mortality burial.

Nutsch, A., and Spire, M., 2004, Carcass disposal: a comprehensive review: National Agricultural Biosecurity Center Consortium.

Pratt, D. L., 2009, Environmental impact of livestock mortalities burial: M.Sc. thesis, University of Saskatchewan, Canada.

Ritter, W. F., and Chirnside, A. E. M., 1995, Impact of dead bird disposal pits on groundwater quality on the Delmarva Peninsula: Bioresource Technology, 53, 105–111
Impact of dead bird disposal pits on groundwater quality on the Delmarva Peninsula:Crossref | GoogleScholarGoogle Scholar | 1:CAS:528:DyaK2MXovFSrtbo%3D&md5=34bc25f763d67240dd93fd40e391d91dCAS |

Song, Y., and Chung, S. H., 2002, Sensitivity analysis and estimation of the depth of investigation in small-loop EM surveys: Geophysics and Geophysical Exploration, 5, 299–308

Song, S. H., Um, J. Y., Cho, I. K., and Jung, C. Y., 2011, Investigation of contamination area from landfill using the small-loop electromagnetic survey: Geophysics and Geophysical Exploration, 14, 158–163

Telford, W. M., Geldart, L. P., and Sheriff, R. E., 1990, Applied geophysics (2nd edition): Cambridge University Press.

US EPA, 2002, Municipal solid waste in the United States: 2000 facts and figures executive summary (No. EPA530-S-02–001).

Won, I. J., 2003, Meter reader – small frequency domain electromagnetic induction sensor: The Leading Edge, 22, 320–322
Meter reader – small frequency domain electromagnetic induction sensor:Crossref | GoogleScholarGoogle Scholar |

Yi, M. J., Kim, J. H., Song, Y., Cho, S. J., Chung, S. H., and Suh, J. H., 2001, Three-dimensional imaging of subsurface structure using resistivity data: Geophysical Prospecting, 49, 483–497
Three-dimensional imaging of subsurface structure using resistivity data:Crossref | GoogleScholarGoogle Scholar |

Yi, M. J., Kim, J. H., and Chung, S. H., 2003, Enhancing the resolving power of least-squares inversion with active constraint balancing: Geophysics, 68, 931–941
Enhancing the resolving power of least-squares inversion with active constraint balancing:Crossref | GoogleScholarGoogle Scholar |