Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity
Cation-exchange capacity (CEC) measurements are widely used to quantify the smectite content in altered rocks. Within this study, we measure the CEC of drill cuttings in four wells from three different high-temperature geothermal areas in Iceland. The CEC measurements in all four wells show similar...
| Published in: | Energies |
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| Language: | English |
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Multidisciplinary Digital Publishing Institute
2020
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| Online Access: | https://doi.org/10.3390/en13215730 |
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ftmdpi:oai:mdpi.com:/1996-1073/13/21/5730/ 2023-08-20T04:07:25+02:00 Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity Tobias Björn Weisenberger Heimir Ingimarsson Gylfi Páll Hersir Ólafur G. Flóvenz 2020-11-02 application/pdf https://doi.org/10.3390/en13215730 EN eng Multidisciplinary Digital Publishing Institute H: Geo-Energy https://dx.doi.org/10.3390/en13215730 https://creativecommons.org/licenses/by/4.0/ Energies; Volume 13; Issue 21; Pages: 5730 cation-exchange capacity hydrothermal systems electrical resistivity clay minerals alteration Iceland image Text 2020 ftmdpi https://doi.org/10.3390/en13215730 2023-08-01T00:23:46Z Cation-exchange capacity (CEC) measurements are widely used to quantify the smectite content in altered rocks. Within this study, we measure the CEC of drill cuttings in four wells from three different high-temperature geothermal areas in Iceland. The CEC measurements in all four wells show similar depth/temperature related pattern, and when comparing the CEC with electrical resistivity logs, we could show that the low resistivity zone coincides with CEC values >5 meq/100 g. The measurements show, in general, an exponential decrease of the CEC with increasing depth. At the facies boundary between the mixed-layer clay and epidote-chlorite zone, the CEC reaches a steady state at about 5 meq/100 g and below that it only decreases slightly within a linear trend with increasing depth. The facies boundary overlaps with the transition where the electrical resistivity logs show an increase in resistivity. It is shown that the measured CEC can be related to the clay mineral alteration within the geothermal system and the CEC reflects the smectite component within the interstratified chlorite/smectite minerals for similar alteration degree. Furthermore, CEC was measured in seven core samples from different alteration zones that had previously been studied in detail with respect to petrophysical and conductivity properties. The results show a clear correlation between CEC and the iso-electrical point, which describes the value of the pore fluid conductivity where transition from surface conductivity to pore fluid conductivity occurs. The presented study shows that the CEC within hydrothermal altered basaltic systems mimics the expandable clay mineral alteration zones and coincides with electrical logs. The presented method can, therefore, be an easy tool to quantify alteration facies within geothermal exploration and drilling projects. Text Iceland MDPI Open Access Publishing Energies 13 21 5730 |
| institution |
Open Polar |
| collection |
MDPI Open Access Publishing |
| op_collection_id |
ftmdpi |
| language |
English |
| topic |
cation-exchange capacity hydrothermal systems electrical resistivity clay minerals alteration Iceland image |
| spellingShingle |
cation-exchange capacity hydrothermal systems electrical resistivity clay minerals alteration Iceland image Tobias Björn Weisenberger Heimir Ingimarsson Gylfi Páll Hersir Ólafur G. Flóvenz Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| topic_facet |
cation-exchange capacity hydrothermal systems electrical resistivity clay minerals alteration Iceland image |
| description |
Cation-exchange capacity (CEC) measurements are widely used to quantify the smectite content in altered rocks. Within this study, we measure the CEC of drill cuttings in four wells from three different high-temperature geothermal areas in Iceland. The CEC measurements in all four wells show similar depth/temperature related pattern, and when comparing the CEC with electrical resistivity logs, we could show that the low resistivity zone coincides with CEC values >5 meq/100 g. The measurements show, in general, an exponential decrease of the CEC with increasing depth. At the facies boundary between the mixed-layer clay and epidote-chlorite zone, the CEC reaches a steady state at about 5 meq/100 g and below that it only decreases slightly within a linear trend with increasing depth. The facies boundary overlaps with the transition where the electrical resistivity logs show an increase in resistivity. It is shown that the measured CEC can be related to the clay mineral alteration within the geothermal system and the CEC reflects the smectite component within the interstratified chlorite/smectite minerals for similar alteration degree. Furthermore, CEC was measured in seven core samples from different alteration zones that had previously been studied in detail with respect to petrophysical and conductivity properties. The results show a clear correlation between CEC and the iso-electrical point, which describes the value of the pore fluid conductivity where transition from surface conductivity to pore fluid conductivity occurs. The presented study shows that the CEC within hydrothermal altered basaltic systems mimics the expandable clay mineral alteration zones and coincides with electrical logs. The presented method can, therefore, be an easy tool to quantify alteration facies within geothermal exploration and drilling projects. |
| format |
Text |
| author |
Tobias Björn Weisenberger Heimir Ingimarsson Gylfi Páll Hersir Ólafur G. Flóvenz |
| author_facet |
Tobias Björn Weisenberger Heimir Ingimarsson Gylfi Páll Hersir Ólafur G. Flóvenz |
| author_sort |
Tobias Björn Weisenberger |
| title |
Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| title_short |
Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| title_full |
Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| title_fullStr |
Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| title_full_unstemmed |
Cation-Exchange Capacity Distribution within Hydrothermal Systems and Its Relation to the Alteration Mineralogy and Electrical Resistivity |
| title_sort |
cation-exchange capacity distribution within hydrothermal systems and its relation to the alteration mineralogy and electrical resistivity |
| publisher |
Multidisciplinary Digital Publishing Institute |
| publishDate |
2020 |
| url |
https://doi.org/10.3390/en13215730 |
| genre |
Iceland |
| genre_facet |
Iceland |
| op_source |
Energies; Volume 13; Issue 21; Pages: 5730 |
| op_relation |
H: Geo-Energy https://dx.doi.org/10.3390/en13215730 |
| op_rights |
https://creativecommons.org/licenses/by/4.0/ |
| op_doi |
https://doi.org/10.3390/en13215730 |
| container_title |
Energies |
| container_volume |
13 |
| container_issue |
21 |
| container_start_page |
5730 |
| _version_ |
1774719044295852032 |