Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone
The oxidation of pyrite is one of the near field processes of the chemical evolution of clay rock planned to host a deep geological radioactive waste repository during operation. Indeed, this process can lead to transitory acidic conditions in the medium (i.e., production of sulphuric acid, carbonic...
| Published in: | Minerals |
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| Main Authors: | , , , , , , , |
| Format: | Text |
| Language: | English |
| Published: |
Multidisciplinary Digital Publishing Institute
2019
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| Subjects: | |
| Online Access: | https://doi.org/10.3390/min9070427 |
| _version_ | 1821489876489469952 |
|---|---|
| author | Héloïse Verron Jérôme Sterpenich Julien Bonnet Franck Bourdelle Régine Mosser-Ruck Catherine Lorgeoux Aurélien Randi Nicolas Michau |
| author_facet | Héloïse Verron Jérôme Sterpenich Julien Bonnet Franck Bourdelle Régine Mosser-Ruck Catherine Lorgeoux Aurélien Randi Nicolas Michau |
| author_sort | Héloïse Verron |
| collection | MDPI Open Access Publishing |
| container_issue | 7 |
| container_start_page | 427 |
| container_title | Minerals |
| container_volume | 9 |
| description | The oxidation of pyrite is one of the near field processes of the chemical evolution of clay rock planned to host a deep geological radioactive waste repository during operation. Indeed, this process can lead to transitory acidic conditions in the medium (i.e., production of sulphuric acid, carbonic acid) which may influence the corrosion kinetics of the carbon steel components of some disposal cells. In order to improve the geochemical modelling of the long-term disposal, the oxidation of pyrite in contact with clays and carbonates at 100 °C must be evaluated. In this study, special attention was paid to the pyrite oxidation rate thanks to an original experimental set-up, involving several pyrite/mineral mixtures and a reactor coupled to a micro gas chromatograph (PO2 and PCO2 monitoring). Although thermodynamic modelling expects that hematite is the most stable phase in a pure pyrite heated system (low pH), experiments show the formation of native sulfur as an intermediate product of the reaction. In the presence of calcite, the pH is neutralized and drives the lower reactivity of pyrite in the absence of native sulfur. The addition of clay phases or other detrital silicates from the claystone had no impact on pyrite oxidation rate. The discrepancies between experiments and thermodynamic modelling are explained by kinetic effects. Two laws were deduced at 100 °C. The first concerns a pure pyrite system, with the following law: r P y = 10 − 4.8 · P O 2 0.5 · t − 0.5 . The second concerns a pyrite/carbonates system: r P y + C a = 10 − 5.1 · P O 2 0.5 · t − 0.5 where PO2 corresponds to the partial pressure of O2 (in bar) and t is time in seconds. Different mechanisms are proposed to explain the evolution with time of the O2 consumption during pyrite oxidation: (i) decrease of the specific or reactive surface area after oxidation of fine grains of pyrite, (ii) decrease of O2 pressure, (iii) growing up of secondary minerals (Fe-oxides or anhydrite in the presence of calcium in the system) on the surface of pyrite ... |
| format | Text |
| genre | Carbonic acid |
| genre_facet | Carbonic acid |
| id | ftmdpi:oai:mdpi.com:/2075-163X/9/7/427/ |
| institution | Open Polar |
| language | English |
| op_collection_id | ftmdpi |
| op_coverage | agris |
| op_doi | https://doi.org/10.3390/min9070427 |
| op_relation | Environmental Mineralogy and Biogeochemistry https://dx.doi.org/10.3390/min9070427 |
| op_rights | https://creativecommons.org/licenses/by/4.0/ |
| op_source | Minerals; Volume 9; Issue 7; Pages: 427 |
| publishDate | 2019 |
| publisher | Multidisciplinary Digital Publishing Institute |
| record_format | openpolar |
| spelling | ftmdpi:oai:mdpi.com:/2075-163X/9/7/427/ 2025-01-16T21:28:29+00:00 Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone Héloïse Verron Jérôme Sterpenich Julien Bonnet Franck Bourdelle Régine Mosser-Ruck Catherine Lorgeoux Aurélien Randi Nicolas Michau agris 2019-07-12 application/pdf https://doi.org/10.3390/min9070427 EN eng Multidisciplinary Digital Publishing Institute Environmental Mineralogy and Biogeochemistry https://dx.doi.org/10.3390/min9070427 https://creativecommons.org/licenses/by/4.0/ Minerals; Volume 9; Issue 7; Pages: 427 pyrite oxidation claystone gas analysis radwaste geological repository Text 2019 ftmdpi https://doi.org/10.3390/min9070427 2023-07-31T22:25:50Z The oxidation of pyrite is one of the near field processes of the chemical evolution of clay rock planned to host a deep geological radioactive waste repository during operation. Indeed, this process can lead to transitory acidic conditions in the medium (i.e., production of sulphuric acid, carbonic acid) which may influence the corrosion kinetics of the carbon steel components of some disposal cells. In order to improve the geochemical modelling of the long-term disposal, the oxidation of pyrite in contact with clays and carbonates at 100 °C must be evaluated. In this study, special attention was paid to the pyrite oxidation rate thanks to an original experimental set-up, involving several pyrite/mineral mixtures and a reactor coupled to a micro gas chromatograph (PO2 and PCO2 monitoring). Although thermodynamic modelling expects that hematite is the most stable phase in a pure pyrite heated system (low pH), experiments show the formation of native sulfur as an intermediate product of the reaction. In the presence of calcite, the pH is neutralized and drives the lower reactivity of pyrite in the absence of native sulfur. The addition of clay phases or other detrital silicates from the claystone had no impact on pyrite oxidation rate. The discrepancies between experiments and thermodynamic modelling are explained by kinetic effects. Two laws were deduced at 100 °C. The first concerns a pure pyrite system, with the following law: r P y = 10 − 4.8 · P O 2 0.5 · t − 0.5 . The second concerns a pyrite/carbonates system: r P y + C a = 10 − 5.1 · P O 2 0.5 · t − 0.5 where PO2 corresponds to the partial pressure of O2 (in bar) and t is time in seconds. Different mechanisms are proposed to explain the evolution with time of the O2 consumption during pyrite oxidation: (i) decrease of the specific or reactive surface area after oxidation of fine grains of pyrite, (ii) decrease of O2 pressure, (iii) growing up of secondary minerals (Fe-oxides or anhydrite in the presence of calcium in the system) on the surface of pyrite ... Text Carbonic acid MDPI Open Access Publishing Minerals 9 7 427 |
| spellingShingle | pyrite oxidation claystone gas analysis radwaste geological repository Héloïse Verron Jérôme Sterpenich Julien Bonnet Franck Bourdelle Régine Mosser-Ruck Catherine Lorgeoux Aurélien Randi Nicolas Michau Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title | Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title_full | Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title_fullStr | Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title_full_unstemmed | Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title_short | Experimental Study of Pyrite Oxidation at 100 °C: Implications for Deep Geological Radwaste Repository in Claystone |
| title_sort | experimental study of pyrite oxidation at 100 °c: implications for deep geological radwaste repository in claystone |
| topic | pyrite oxidation claystone gas analysis radwaste geological repository |
| topic_facet | pyrite oxidation claystone gas analysis radwaste geological repository |
| url | https://doi.org/10.3390/min9070427 |