All Issue

2020 Vol.25, Issue 1S1 Preview Page
30 June 2020. pp. 86-100
Abstract
References
1

Abdel Aal, G.Z., Slater, L.D., and Atekwana, E.A., 2006, Induced-polarization measurements on unconsolidated sedi-ments from a site of active hydrocarbon biodegradation, Geo-physics, 71(2), H13-H24.

10.1190/1.2187760
2

Abdel Aal, G.Z., Atekwana, E., Radzikowski, S., and Rossbach, S., 2009, Effect of bacterial adsorption on low frequency elec-trical properties of clean quartz sands and iron-oxide coated sands, Geophys. Res. Lett., 36(4).

10.1029/2008GL036196
3

Abdel Aal, G.Z., Atekwana, E.A., Slater, L.D., and Atekwana, E.A., 2004, Effects of microbial processes on electrolytic and interfacial electrical properties of unconsolidated sediments, Geophys. Res. Lett., 31(12).

10.1029/2004GL020030
4

Abdullahi, N.K., Osazuwa, I.B., and Sule, P.O., 2011, Applica-tion of integrated geophysical techniques in the investigation of groundwater contamination: a case study of municipal solid waste leachate, Ozean. J. Appl. Sci., 4(1), 7-25.

5

Abu-Zeid, N., Bianchini, G., Santarato, G., and Vaccaro, C., 2004, Geochemical characterisation and geophysical mapping of Landfill leachates: the Marozzo canal case study (NE Italy), Environ. Geol., 45(4), 439-447.

10.1007/s00254-003-0895-x
6

Anderson, W.G., 1986, Wettability literature survey-part 1: rock/ oil/brine interactions and the effects of core handling on wetta-bility, Journal of petroleum technology, 38(10), 1-125.

10.2118/13932-PA
7

Atekwana, E. and Atekwana, E., 2010, Geophysical signatures of microbial activity at hydrocarbon contaminated sites: a review, Survev, Geophysics., 31(2), 247-283.

10.1007/s10712-009-9089-8
8

Atekwana, E.A., Sauck, W.A., and Werkema Jr, D.D., 2000, Investigations of geoelectrical signatures at a hydrocarbon con-taminated site, J. Appl. Geophy., 44(2-3), 167-180.

10.1016/S0926-9851(98)00033-0
9

Atekwana, Estella A., D. Dale Werkema, and Eliot A. Ate-kwana, 2006, Biogeophysics: The effects of microbial pro-cesses on geophysical properties of the shallow subsurface, Applied hydrogeophysics, Springer, Dordrecht, 161-193.

10.1007/978-1-4020-4912-5_6
10

Blondel, A., Schmutz, M., Franceschi, M., Tichané, F., and Carles, M., 2014, Temporal evolution of the geoelectrical response on a hydrocarbon contaminated site, J. Appl. Geophy., 103, 161-171.

10.1016/j.jappgeo.2014.01.013
11

Börner, F., Gruhne, M., and Schön, J., 1993, Contamination indications derived from electrical properties in the low fre-quency range, Geophys. Prospect., 41(1), 83-98.

10.1111/j.1365-2478.1993.tb00566.x
12

Cardarelli, E. and Di Filippo, G., 2009, Electrical resistivity and induced polarization tomography in identifying the plume of chlorinated hydrocarbons in sedimentary formation: a case study in Rho (Milan-Italy). Waste Manag. Res., 27(6), 595-602.

10.1177/0734242X09102524
13

Carlson, K.M., Goodman, L.K., and May-Tobin, C.C., 2015, Modeling relationships between water table depth and peat soil carbon loss in Southeast Asian plantations, Environ. Res. Lett., 10(7), 074006.

10.1088/1748-9326/10/7/074006
14

Carlson, N.R. and Urquhart, S.A., 2004, February. Comparisons Of Ip And Resistivity Data At Several Old, Buried Landfills. Proceedings of the In 17th EEGS Symposium on the Applica-tion of Geophysics to Engineering and Environmental Problems (pp. cp-186). European Association of Geoscientists & Engi-neers, p. cp-186.

15

Cassiani, G., Kemna, A., Villa, A., and Zimmermann, E., 2009, Spectral induced polarization for the characterization of free-phase hydrocarbon contamination of sediments with low clay content, Near Surf. Geophys., 7(5-6), 547-562.

10.3997/1873-0604.2009028
16

Cassidy, J., 2002, The role of microtine rodents in contaminant/ solute transport at the landscape level (Doctoral dissertation, MS Thesis, Oregon State University, Corvallis).

17

Cozzarelli, I.M., Baedecker, M.J., Eganhouse, R.P., and Goer-litz, D.F., 1994, The geochemical evolution of low-molecular-weight organic acids derived from the degradation of petroleum contaminants in groundwater, Geochimica et Cosmochimica Acta, 58(2), 863-877.

10.1016/0016-7037(94)90511-8
18

Davis, C.A., Atekwana, E., Atekwana, E., Slater, L.D., Ross-bach, S., and Mormile, M.R., 2006, Microbial growth and bio-film formation in geologic media is detected with complex conductivity measurements, Geophys. Res. Lett, 33(18).

10.1029/2006GL027312
19

Doherty, R., Kulessa, B., Ferguson, A.S., Larkin, M.J., Kula-kov, L.A., and Kalin, R.M., 2010, A microbial fuel cell in con-taminated ground delineated by electrical self-potential and normalized induced polarization data, J. Geophys. Res: Biogeo-sciences, 115(G3).

10.1029/2009JG001131
20

Draskovits, P., 1994, Application of induced polarization meth-ods in integrated studies of ground water exploration and char-acterization of subsurface contamination, In The John S. Sumner Mem. Int. Workshop Induced Polarization (IP) in Mining and The Environment. Dep. Min, Geol. Eng., Univ. Arizona, Tucson, AZ.

21

Frangos, W., and Andrezal, T., 1994, IPmeasurements at con-taminant and toxic waste sites in Slovakia. In The John S. Sumner Mem. Int. Workshop Induced Polarization (IP) in Min-ing and The Environment. Dep. Min, Geol. Eng., Univ. Arizona, Tucson, AZ.

22

Gazoty, A., Fiandaca, G., Pedersen, J., Auken, E., and Christian-sen, A.V., 2012, Mapping of landfills using time-domain spec-tral induced polarization data: the Eskelund case study, Near Surf. Geophys., 10(6), 575-586.

10.3997/1873-0604.2012046
23

Jegede, A.J., Aimufua, G.I.O., and Akosu, N.I., 2012, Elec-tronic Voting: A Panacea for electoral irregularities in develop-ing countries, International Journal of Science and Knowledge, 1(1), 17-37.

24

Johansson, B., Jones, S., Dahlin, T. and Flyhammar, P., 2007, September. Comparisons of 2D-and 3D-inverted resistivity data as well as of resistivity-and IP-surveys on a landfill. Proceed-ings of the In Near Surface 2007-13th EAGE European Meet-ing of Environmental and Engineering Geophysics.

10.3997/2214-4609.20146658
25

Kim, B., Nam, M.J., Jang, H., Jang, H., Son, J. S., and Kim, H.J., 2017, The Principles and Practice of Induced Polarization Method, Geophys. and Geophys. Explor., 20(2), 100-113.

26

Kühlers, D., Bethge, E., Hillebrand, G., Hollert, H., Fleig, M., Lehmann, B., Maier, M., Mohrlok, U., and Wölz, J., 2009, Con-taminant transport to public water supply wells via flood water retention areas, Nat. Hazards Earth Syst. Sci., 9(4), 1047-1058.

10.5194/nhess-9-1047-2009
27

Lesmes, D.P. and Frye, K.M., 2001, Influence of pore fluid chemistry on the complex conductivity and induced polariza-tion responses of Berea sandstone, J. Geophys. Res. Solid Earth, 106(B3), 4079-4090.

10.1029/2000JB900392
28

Maier, R.M., Pepper, I.L., and Gerba, C.P., 2009, Environmen-tal microbiology (Vol. 397). Academic press.

29

Martin, T. and Paul, C.J., 2018, IP lab measurements on E. coli-sand-mixtures. Proceedings of the In 5th International Work-shop on Induced Polarization.

30

Maurya, P.K., 2017, Imaging lithology, water conductivity, and hydraulic permeability at contaminated sites with induced polar-ization. Aarhus university, Denmark.

31

Maurya, P.K., Balbarini, N., Møller, I., Rønde, V., Christiansen, A.V., Bjerg, P.L., Auken, E., and Fiandaca, G., 2018, Subsurface imaging of water electrical conductivity, hydraulic permeability and lithology at contaminated sites by induced polarization, Geophys. J. In., 213(2), 770-785.

10.1093/gji/ggy018
32

Mewafy, F.M., Werkema Jr, D.D., Atekwana, E.A., Slater, L.D., Aal, G.A., Revil, A., and Ntarlagiannis, D., 2013, Evidence that bio-metallic mineral precipitation enhances the complex con-ductivity response at a hydrocarbon contaminated site, J. Appl. Geophy., 98, 113-123.

10.1016/j.jappgeo.2013.08.011
33

Ntarlagiannis, D. and Ferguson, A., 2008, SIP response of arti-ficial biofilms, Geophysics, 74(1), A1-A5.

10.1190/1.3031514
34

Ntarlagiannis, D., Williams, K.H., Slater, L., and Hubbard, S., 2005, Low-frequency electrical response to microbial induced sulfide precipitation, J. Geophys. Res. Biogeosciences, 110(G2).

10.1029/2005JG000024
35

Ntarlagiannis, D., Yee, N., and Slater, L., 2005, On the low-fre-quency electrical polarization of bacterial cells in sands, Geo-phys. Res. Lett., 32(24).

10.1029/2005GL024751
36

Olhoeft, G.R., 1985, Low-frequency electrical properties, Geo-physics, 50(12), 2492-2503.

10.1190/1.1441880
37

Placencia-Gómez, E., Parviainen, A., Slater, L., and Leveinen, J., 2015, Spectral induced polarization (SIP) response of mine tailings, J. Contam. Hydrol., 173, 8-24.

10.1016/j.jconhyd.2014.12.002
38

Power, C., Tsourlos, P., Ramasamy, M., Nivorlis, A., and Mkan-dawire, M., 2018, Combined DC resistivity and induced polar-ization (DC-IP) for mapping the internal composition of a mine waste rock pile in Nova Scotia, Canada, J. Appl. Geophy., 150, 40-51.

10.1016/j.jappgeo.2018.01.009
39

Revil, A., Schmutz, M., and Batzle, M.L., 2011, Influence of oil wettability upon spectral induced polarization of oil-bearing sands, Geophysics, 76(5), A31-A36.

10.1190/geo2011-0006.1
40

Revil, A., Wu, Y., Karaoulis, M., Hubbard, S.S., Watson, D.B., and Eppehimer, J.D., 2013, Geochemical and geophysical responses during the infiltration of fresh water into the contam-inated saprolite of the Oak Ridge Integrated Field Research Challenge site, Tennessee, Water Resour. Res., 49(8), 4952-4970.

10.1002/wrcr.20380
41

Reynolds, J.M., 1997, An Introduction to Applied and Environ-mental Geophysics, John Wiley, Chichester, U. K.

42

Schmutz, M., Blondel, A., and Revil, A., 2012, Saturation dependence of the quadrature conductivity of oil-bearing sands, Geophys. Res. Lett., 39(3).

10.1029/2011GL050474
43

Schmutz, M., Revil, A., Vaudelet, P., Batzle, M., Viñao, P.F., and Werkema, D.D., 2010, Influence of oil saturation upon spectral induced polarization of oil-bearing sands, Geophys. J. In., 183(1), 211-224.

10.1111/j.1365-246X.2010.04751.x
44

Schwartz, N., Shalem, T., and Furman, A., 2014, The effect of organic acid on the spectral-induced polarization response of soil, Geophys. J. In., 197(1), 269-276.

10.1093/gji/ggt529
45

Slater, L.D. and Lesmes, D., 2002, IP interpretation in environ-mental investigations, Geophysics, 67(1), 77-88.

10.1190/1.1451353
46

Vanhala, H., Soininen, H., and Kukkonen, I., 1992, Detecting organicchemical contaminants by spectral-induced polarization method in glacial till environment, Geophysics, 57(8), 1014-1017.

10.1190/1.1443312
47

Vanhala, H., 1997, Mapping oil-contaminated sand and till with the spectral induced polarization (SIP) method, Geophys. Pros-pect, 45(2), 303-326.

10.1046/j.1365-2478.1997.00338.x
48

Yu, H., Kim, B., Song, S.Y., Cho, S.O., Caesary, D., and Nam, M.J., 2019, Change in Physical Properties depending on Con-taminants and Introduction to Case Studies of Geophysical Sur-veys Applied to Contaminant Detection, Geophys. and Geophys. Explor., 22(3), 132-148.

Information
  • Publisher :The Korean Society of Soil and Groundwater Environment
  • Publisher(Ko) :한국지하수토양환경학회
  • Journal Title :Journal of Soil and Groundwater Environment
  • Journal Title(Ko) :지하수토양환경
  • Volume : 25
  • No :1
  • Pages :86-100
  • Received Date : 2020-05-28
  • Revised Date : 2020-06-12
  • Accepted Date : 2020-06-23