6533b86ffe1ef96bd12cdbff

RESEARCH PRODUCT

Constraining electric resistivity tomography by direct push electric conductivity logs and vibracores: An exemplary study of the Fiume Morto silted riverbed (Ostia Antica, western Italy)

Ercan ErkulDennis WilkenAndreas VöttTina WunderlichRebekka MeckingPeter FischerHanna HadlerMichael HeinzelmannWolfgang RabbelThomas Günther

subject

010504 meteorology & atmospheric sciencesApparent resistivityMineralogyInversion (meteorology)010502 geochemistry & geophysics01 natural sciencesGeophysicsGeochemistry and PetrologyElectrical resistivity and conductivityBoundary value problemTomographyGeology0105 earth and related environmental sciencesElectric resistivity

description

The inversion of geoelectric data is nonunique. Therefore, electric resistivity tomography (ERT) usually results in different subsurface models that fit observed apparent resistivity values equally well. To reduce the uncertainty, constraints on the geometry and resistivity of subsurface structures can be incorporated into the ERT inversion. We test different ways of constraining ERT by applying (1) improved starting models, (2) structural constraints, and (3) structural and resistivity constraints. A priori information is needed for these approaches, which is acquired from direct push electrical conductivity (DP-EC) logs and vibracores in our study. We found that adapting high vertical resolution of DP-EC logs to coarser ERT resolution requires blocking of the logs. These blocked logs can be used for constraining the ERT inversion with resistivity and structural constraints along so-called regions around the log locations, which was found to be the best approach. In this case, ground truthing with additional DP-EC logs that were not used for constraining showed the lowest root-mean-square error between logs and ERT model.

yearjournalcountryeditionlanguage
2018-05-01GEOPHYSICS
https://doi.org/10.1190/geo2016-0660.1