Academic literature on the topic 'Ag2O getter'
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Journal articles on the topic "Ag2O getter":
Chlique, Christophe, David Lambertin, Kévin Galliez, Véronique Labed, Adeline Dannoux-Papin, Stéphane Jobic, Philippe Deniard, and Elisa Leoni. "Effect of gamma irradiation on MnO2/Ag2O hydrogen getter." Journal of Nuclear Materials 458 (March 2015): 162–67. http://dx.doi.org/10.1016/j.jnucmat.2014.11.128.
Galliez, Kévin, Philippe Deniard, David Lambertin, Stéphane Jobic, and Florence Bart. "Influence of MnO2 polymorphism form on MnO2/Ag2O hydrogen getter." Journal of Nuclear Materials 438, no. 1-3 (July 2013): 261–67. http://dx.doi.org/10.1016/j.jnucmat.2013.03.053.
Chlique, Christophe, David Lambertin, Fabien Frizon, Philippe Deniard, and Stéphane Jobic. "Effect of temperature on the γ-MnO2/“Ag2O” hydrogen getter structure." Fusion Engineering and Design 112 (November 2016): 475–79. http://dx.doi.org/10.1016/j.fusengdes.2016.06.014.
Lanier, S., C. A. Davy, C. Albert-Mercier, O. Farcy, C. Cau Dit Coumes, and D. Lambertin. "Novel Portland cement matrices incorporating a γ-MnO2/Ag2O hydrogen/tritium getter -Structure changes and trapping performance." Journal of Nuclear Materials, June 2022, 153819. http://dx.doi.org/10.1016/j.jnucmat.2022.153819.
Garnero, Gabriel. "La Estacionalidad hídrica y el transporte terrestre: Flujos del agua y sistema de comunicaciones en el oeste de Córdoba (1850-1930)." Naveg@mérica. Revista electrónica editada por la Asociación Española de Americanistas, no. 32 (March 20, 2024). http://dx.doi.org/10.6018/nav.549791.
Dissertations / Theses on the topic "Ag2O getter":
Reeb, Charles. "Synthèse et caractérisation de composites à base de matériaux alcali-activés incorporant des huiles minérales pour la gestion des huiles tritiées." Electronic Thesis or Diss., Centrale Lille Institut, 2022. http://www.theses.fr/2022CLIL0020.
This work deals with the conditioning of tritiated industrial oils in the context of nuclear wastes that are still deprived of an appropriate treatment solution. The strategy consists in directly conditioning model mineral oils in alkali-activated materials (AAM), additionally functionalized with a γ-MnO2/Ag2O hydrogen/tritium getter. Geopolymer (GEO) and alkali-activated blast furnace slag (AABFS) are considered as AAM. In the presence of surfactants, the oil was successfully emulsified (small and homogeneous droplets) in both types of AAM. Two surfactant mechanisms are distinguished acting by: 1) decreasing the interfacial tension or 2) promoting oil-particles interactions. Mechanism 1 should be favored if workability of fresh mixtures is required, while mechanism 2 should be targeted to provide a better confinement of oil owing to strong oil-particles interactions. After curing, AAM-OIL composites are obtained. There is no influence of the oil and surfactants on the setting time and strength development of AAM. The main reaction products (C-A-S-H in AABFS and N-A-S-H in GEO) are not impacted. However, the addition of surfactants leads to increased porosity of AAM due to air bubbles stabilization. AAM-OIL composites immobilizing 20%vol. of oil all have compressive strengths higher than 20 MPa, which is a more than the 8 MPa required from ANDRA. Overall, according to both fresh and hardened states observations, GEO exhibit higher performances for the immobilization of oil than AABFS. The efficiency of the γ-MnO2/Ag2O getter was assessed in AAM via in-situ hydrogen production by gamma irradiations or magnesium corrosion. Both types of experiments agree to the higher performances of the getter in GEO than in AABFS. This is explained by reducing sulfur species present in AABFS, which react with the oxidizing getter components. Finally, wetting measurements demonstrated that industrial oils have an excellent affinity for GEO, testifying that long-term water seepage is not likely to dislodge them from GEO-OIL composites. In the context of nuclear waste management, GEO functionalized with γ-MnO2/Ag2O getter appears as a promising option for disposal of tritiated oils. However, additional investigations of HTO confinement need to be performed that could renew the interest of using AABFS
Books on the topic "Ag2O getter":
Gettier, Edmund L. Introduction. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198724551.003.0001.