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@ARTICLE{Kessouri:873369,
author = {Kessouri, P. and Furman, A. and Huisman, J. A. and Martin,
T. and Mellage, A. and Ntarlagiannis, D. and Bücker, M. and
Ehosioke, S. and Fernandez, P. and Flores‐Orozco, A. and
Kemna, A. and Nguyen, F. and Pilawski, T. and Saneiyan, S.
and Schmutz, M. and Schwartz, N. and Weigand, M. and Wu, Y.
and Zhang, C. and Placencia‐Gomez, E.},
title = {{I}nduced polarization applied to biogeophysics: recent
advances and future prospects},
journal = {Near surface geophysics},
volume = {17},
number = {6},
issn = {1873-0604},
address = {Houten},
publisher = {EAGE},
reportid = {FZJ-2020-00681},
pages = {595 - 621},
year = {2019},
abstract = {This paper provides an update on the fast‐evolving field
of the induced polarization method applied to biogeophysics.
It emphasizes recent advances in the understanding of the
induced polarization signals stemming from biological
materials and their activity, points out new developments
and applications, and identifies existing knowledge gaps.
The focus of this review is on the application of induced
polarization to study living organisms: soil microorganisms
and plants (both roots and stems). We first discuss observed
links between the induced polarization signal and microbial
cell structure, activity and biofilm formation. We provide
an up‐to‐date conceptual model of the electrical
behaviour of the microbial cells and biofilms under the
influence of an external electrical field. We also review
the latest biogeophysical studies, including work on
hydrocarbon biodegradation, contaminant sequestration, soil
strengthening and peatland characterization. We then
elaborate on the induced polarization signature of the
plant‐root zone, relying on a conceptual model for the
generation of biogeophysical signals from a plant‐root
cell. First laboratory experiments show that single roots
and root system are highly polarizable. They also present
encouraging results for imaging root systems embedded in a
medium, and gaining information on the mass density
distribution, the structure or the physiological
characteristics of root systems. In addition, we highlight
the application of induced polarization to characterize wood
and tree structures through tomography of the stem. Finally,
we discuss up‐ and down‐scaling between laboratory and
field studies, as well as joint interpretation of induced
polarization and other environmental data. We emphasize the
need for intermediate‐scale studies and the benefits of
using induced polarization as a time‐lapse monitoring
method. We conclude with the promising integration of
induced polarization in interdisciplinary mechanistic models
to better understand and quantify subsurface biogeochemical
processes.},
cin = {IBG-3},
ddc = {550},
cid = {I:(DE-Juel1)IBG-3-20101118},
pnm = {255 - Terrestrial Systems: From Observation to Prediction
(POF3-255)},
pid = {G:(DE-HGF)POF3-255},
typ = {PUB:(DE-HGF)16},
UT = {WOS:000594614800003},
doi = {10.1002/nsg.12072},
url = {https://juser.fz-juelich.de/record/873369},
}
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