Image-D5.6: Mt-Inversion Techniques With External Constraints

This report describes MT-inversion techniques with external constraints, Deliverable D5.6 within the IMAGE project. Report analysing the results of MT-inversion techniques with external contraints, describing optimal MT layout and data modelling for obtaining maximum information from MT surveys, inc...

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Main Authors: Hersir, Gylfi Páll, Manzella, Adele
Format: Text
Language:English
Published: Zenodo 2017
Subjects:
geothermal energy
exploration
MT-Inversion
data modelling
iceland
italy
geophysics
Greenfield
Hengill
Iceland
Online Access:https://dx.doi.org/10.5281/zenodo.1288708
https://zenodo.org/record/1288708
id ftdatacite:10.5281/zenodo.1288708
record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language English
topic geothermal energy
exploration
MT-Inversion
data modelling
iceland
italy
geophysics
spellingShingle geothermal energy
exploration
MT-Inversion
data modelling
iceland
italy
geophysics
Hersir, Gylfi Páll
Manzella, Adele
Image-D5.6: Mt-Inversion Techniques With External Constraints
topic_facet geothermal energy
exploration
MT-Inversion
data modelling
iceland
italy
geophysics
description This report describes MT-inversion techniques with external constraints, Deliverable D5.6 within the IMAGE project. Report analysing the results of MT-inversion techniques with external contraints, describing optimal MT layout and data modelling for obtaining maximum information from MT surveys, including recommendations for opitmised MT site spacing for different a-priori constraints. The first part of the report, which was performed by ISOR, discusses the origin and nature of the static shifts and some tested methods for static shift correction, i.e. joint 1D inversion of co-located TEM and MT and spatial filtering and statistical assumptions about the shifts. A software is introduced which inverts the two datasets for both the resistivity model and the shift of the MT. Besides determining the static shift, joint inversion is an important quality check of the TEM and MT data sets, i.e. weather they are compatible. In EM surveying, software should be used make a preliminary joint inversion of TEM and MT at base camp as a quality control to make sure the field mission is not terminated until god quality data have been collected. Finally, the claim that 3D inversion of MT can deal with the static shifts, i.e. introduce shallow resistivity structures (not resolved by the data) to account for the shifts is tested. The second part was done by ISOR. On one hand the depth-location of a low-resistivity anomaly, as observed from borehole data, is build into the starting model, giving the program a headstart into gaining information on the resistivity in the survey area and on the other hand information on the ductile-brittle bounday location is used to infer the location of a deep low-resistivity anomaly, which is put into the starting model of the inversion. Several tests have been done on the site spacing in MT for 3D inversion.n This was done for MT data from the Hengill area in SW-Iceland, starting with a measurment and model grid of 1 km by 1 km (see, Árnason et al., 2010). Later a measurement and model grid seize of 500 m by 500 m was tested which improved the resolution significantly for the uppermost 1 to 2 km (Árnason, pers. comm., June 2017). Finally, a measure-ment and model grid seize 250 m by 250 m was tested (Benediktsdóttir, pers. comm., June 2017). It only improved the resolution moderately. In the third part performed by CNR, an integrated approach is proposed that greatly improved the knowledge on the deep structures of the system on the basis of the critical review of deep well data, geological and geophysical data and the analysis of new and previously acquired MT data in the Larderello-Travale field. Resistivity models by 2D deterministic inversion was achieved, focusing on the understanding of the reliability of the a-priori model for the inversion procedure. Three sets of starting models were implemented and tested: A homogeneous (without external constraints), a geological model (from the integrated model) and finally an interpolation of 1D models. The resulting models constrained with detailed and accurate geological information as well as using 1D models showed higher resolution than those unconstrained (i.e. from homogeneous half-space). It is demonstrated how the a-priori information from the analysis of MT data, i.e. by PSO optimization in this case, greatly improved the inversion results even those geologically constrained, which is not a trivial issue for the exploration of geothermal greenfield, due to lack of underground data. : FP7
format Text
author Hersir, Gylfi Páll
Manzella, Adele
author_facet Hersir, Gylfi Páll
Manzella, Adele
author_sort Hersir, Gylfi Páll
title Image-D5.6: Mt-Inversion Techniques With External Constraints
title_short Image-D5.6: Mt-Inversion Techniques With External Constraints
title_full Image-D5.6: Mt-Inversion Techniques With External Constraints
title_fullStr Image-D5.6: Mt-Inversion Techniques With External Constraints
title_full_unstemmed Image-D5.6: Mt-Inversion Techniques With External Constraints
title_sort image-d5.6: mt-inversion techniques with external constraints
publisher Zenodo
publishDate 2017
url https://dx.doi.org/10.5281/zenodo.1288708
https://zenodo.org/record/1288708
long_lat ENVELOPE(-27.635,-27.635,-80.759,-80.759)
ENVELOPE(-21.306,-21.306,64.078,64.078)
geographic Greenfield
Hengill
geographic_facet Greenfield
Hengill
genre Iceland
genre_facet Iceland
op_relation https://dx.doi.org/10.5281/zenodo.1288709
op_rights Open Access
info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.5281/zenodo.1288708
https://doi.org/10.5281/zenodo.1288709
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spelling ftdatacite:10.5281/zenodo.1288708 2023-05-15T16:51:20+02:00 Image-D5.6: Mt-Inversion Techniques With External Constraints Hersir, Gylfi Páll Manzella, Adele 2017 https://dx.doi.org/10.5281/zenodo.1288708 https://zenodo.org/record/1288708 en eng Zenodo https://dx.doi.org/10.5281/zenodo.1288709 Open Access info:eu-repo/semantics/openAccess geothermal energy exploration MT-Inversion data modelling iceland italy geophysics Text Project deliverable article-journal ScholarlyArticle 2017 ftdatacite https://doi.org/10.5281/zenodo.1288708 https://doi.org/10.5281/zenodo.1288709 2021-11-05T12:55:41Z This report describes MT-inversion techniques with external constraints, Deliverable D5.6 within the IMAGE project. Report analysing the results of MT-inversion techniques with external contraints, describing optimal MT layout and data modelling for obtaining maximum information from MT surveys, including recommendations for opitmised MT site spacing for different a-priori constraints. The first part of the report, which was performed by ISOR, discusses the origin and nature of the static shifts and some tested methods for static shift correction, i.e. joint 1D inversion of co-located TEM and MT and spatial filtering and statistical assumptions about the shifts. A software is introduced which inverts the two datasets for both the resistivity model and the shift of the MT. Besides determining the static shift, joint inversion is an important quality check of the TEM and MT data sets, i.e. weather they are compatible. In EM surveying, software should be used make a preliminary joint inversion of TEM and MT at base camp as a quality control to make sure the field mission is not terminated until god quality data have been collected. Finally, the claim that 3D inversion of MT can deal with the static shifts, i.e. introduce shallow resistivity structures (not resolved by the data) to account for the shifts is tested. The second part was done by ISOR. On one hand the depth-location of a low-resistivity anomaly, as observed from borehole data, is build into the starting model, giving the program a headstart into gaining information on the resistivity in the survey area and on the other hand information on the ductile-brittle bounday location is used to infer the location of a deep low-resistivity anomaly, which is put into the starting model of the inversion. Several tests have been done on the site spacing in MT for 3D inversion.n This was done for MT data from the Hengill area in SW-Iceland, starting with a measurment and model grid of 1 km by 1 km (see, Árnason et al., 2010). Later a measurement and model grid seize of 500 m by 500 m was tested which improved the resolution significantly for the uppermost 1 to 2 km (Árnason, pers. comm., June 2017). Finally, a measure-ment and model grid seize 250 m by 250 m was tested (Benediktsdóttir, pers. comm., June 2017). It only improved the resolution moderately. In the third part performed by CNR, an integrated approach is proposed that greatly improved the knowledge on the deep structures of the system on the basis of the critical review of deep well data, geological and geophysical data and the analysis of new and previously acquired MT data in the Larderello-Travale field. Resistivity models by 2D deterministic inversion was achieved, focusing on the understanding of the reliability of the a-priori model for the inversion procedure. Three sets of starting models were implemented and tested: A homogeneous (without external constraints), a geological model (from the integrated model) and finally an interpolation of 1D models. The resulting models constrained with detailed and accurate geological information as well as using 1D models showed higher resolution than those unconstrained (i.e. from homogeneous half-space). It is demonstrated how the a-priori information from the analysis of MT data, i.e. by PSO optimization in this case, greatly improved the inversion results even those geologically constrained, which is not a trivial issue for the exploration of geothermal greenfield, due to lack of underground data. : FP7 Text Iceland DataCite Metadata Store (German National Library of Science and Technology) Greenfield ENVELOPE(-27.635,-27.635,-80.759,-80.759) Hengill ENVELOPE(-21.306,-21.306,64.078,64.078)

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