Geoelectrical signatures of redox processes

Lancaster Environment Centre

Associated organisational unit

Water Science

Electronic data

20190115_Fernandezetal_EAGEAnnual1
Accepted author manuscript, 647 KB, PDF document

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Research output: Contribution to conference - Without ISBN/ISSN › Conference paper

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Geoelectrical signatures of redox processes. / Fernandez, P.M.; Bloem, E.; Binley, A. et al.
2019. Paper presented at 81st EAGE Conference and Exhibition 2019, London, United Kingdom.

Research output: Contribution to conference - Without ISBN/ISSN › Conference paper

Harvard

Fernandez, PM, Bloem, E, Binley, A & French, HK 2019, 'Geoelectrical signatures of redox processes', Paper presented at 81st EAGE Conference and Exhibition 2019, London, United Kingdom, 3/06/19 - 6/06/19.

APA

Fernandez, P. M., Bloem, E., Binley, A., & French, H. K. (2019). Geoelectrical signatures of redox processes. Paper presented at 81st EAGE Conference and Exhibition 2019, London, United Kingdom.

Vancouver

Fernandez PM, Bloem E, Binley A, French HK. Geoelectrical signatures of redox processes. 2019. Paper presented at 81st EAGE Conference and Exhibition 2019, London, United Kingdom.

Author

Fernandez, P.M. ; Bloem, E. ; Binley, A. et al. / Geoelectrical signatures of redox processes. Paper presented at 81st EAGE Conference and Exhibition 2019, London, United Kingdom.

Bibtex

@conference{636e3d4531754cf2abba21119184373b,

title = "Geoelectrical signatures of redox processes",

abstract = "Common redox potential sensors provide point measurements and are error prone. Destructive sampling can cause contact with air which will influence the redox state. Hence, assessing redox conditions in soil is challenging. Redox sensitive reactions like the degradation of organic contaminants will change water chemistry and geophysical properties. We explored geophysical techniques ERT and SIP to observe the degradation processes of Propylene Glycol (PG), a de-icing chemical used at airports. Two laboratory experiments were performed to monitor changes caused by PG degradation: 1) 3D ERT was measured, every week, in four sand tanks. One rich in oxides. 2) SIP was measured, every three days, in twenty-six oxides rich sand columns. In both experiments PG was applied just above the water table. ERT - When iron and manganese oxides were available, degradation reduced resistivity. When oxides were unavailable, the electrical resistivity increased, most likely due to methane production which reduced water saturation. SIP - An increase of the real conductivity was associated with the metal ions release but independent of the frequency. Also an increase of phase angle and imaginary conductivity at frequencies below 1Hz that precede the ion release was observed in the water.",

author = "P.M. Fernandez and E. Bloem and A. Binley and H.K. French",

year = "2019",

month = jun,

day = "6",

language = "English",

note = "81st EAGE Conference and Exhibition 2019 ; Conference date: 03-06-2019 Through 06-06-2019",

}

RIS

TY - CONF

T1 - Geoelectrical signatures of redox processes

AU - Fernandez, P.M.

AU - Bloem, E.

AU - Binley, A.

AU - French, H.K.

N1 - Conference code: 81st

PY - 2019/6/6

Y1 - 2019/6/6

N2 - Common redox potential sensors provide point measurements and are error prone. Destructive sampling can cause contact with air which will influence the redox state. Hence, assessing redox conditions in soil is challenging. Redox sensitive reactions like the degradation of organic contaminants will change water chemistry and geophysical properties. We explored geophysical techniques ERT and SIP to observe the degradation processes of Propylene Glycol (PG), a de-icing chemical used at airports. Two laboratory experiments were performed to monitor changes caused by PG degradation: 1) 3D ERT was measured, every week, in four sand tanks. One rich in oxides. 2) SIP was measured, every three days, in twenty-six oxides rich sand columns. In both experiments PG was applied just above the water table. ERT - When iron and manganese oxides were available, degradation reduced resistivity. When oxides were unavailable, the electrical resistivity increased, most likely due to methane production which reduced water saturation. SIP - An increase of the real conductivity was associated with the metal ions release but independent of the frequency. Also an increase of phase angle and imaginary conductivity at frequencies below 1Hz that precede the ion release was observed in the water.

AB - Common redox potential sensors provide point measurements and are error prone. Destructive sampling can cause contact with air which will influence the redox state. Hence, assessing redox conditions in soil is challenging. Redox sensitive reactions like the degradation of organic contaminants will change water chemistry and geophysical properties. We explored geophysical techniques ERT and SIP to observe the degradation processes of Propylene Glycol (PG), a de-icing chemical used at airports. Two laboratory experiments were performed to monitor changes caused by PG degradation: 1) 3D ERT was measured, every week, in four sand tanks. One rich in oxides. 2) SIP was measured, every three days, in twenty-six oxides rich sand columns. In both experiments PG was applied just above the water table. ERT - When iron and manganese oxides were available, degradation reduced resistivity. When oxides were unavailable, the electrical resistivity increased, most likely due to methane production which reduced water saturation. SIP - An increase of the real conductivity was associated with the metal ions release but independent of the frequency. Also an increase of phase angle and imaginary conductivity at frequencies below 1Hz that precede the ion release was observed in the water.

M3 - Conference paper

T2 - 81st EAGE Conference and Exhibition 2019

Y2 - 3 June 2019 through 6 June 2019

ER -

Research

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