Investigation of self-desiccating cement-based materials for dihydrogen sequestration: Interactions between γ-MnO2/Ag2CO3 getter and the cement matrix

Mitigating the release of dihydrogen resulting from metal corrosion or water radiolysis is an important issue for the disposal of certain types of cemented radwaste packages. The approach investigated in this work consists in adding an oxide getter (γ-MnO2/Ag2CO3) to the cement matrix. Since the efficiency of the getter decreases under wet environment, two self-desiccating binders (calcium sulfo-aluminate and magnesium potassium phosphate cements), are used to obtain significant desaturation of the pore network by the sole hydration reactions. The getter slightly influences the rate of cement hydration at early age, but has no effect afterwards. Sorption of ions released by dissolution of cement phases onto γ-MnO2 is evidenced, as well as partial or total destabilization of silver carbonate. Nevertheless, the getter still enables to reduce strongly the outgassing of dihydrogen from mortars encapsulating Al-metal, which opens new perspectives to improve the conditioning of waste producing H2 in a cement matrix. •Design of cement-based materials for hydrogen sequestration•Dispersion of an oxide getter (87 % γ-MnO2 – 13 % Ag2CO3) in the cement matrix•Limited influence on calcium sulfoaluminate and magnesium phosphate cements hydration•Sorption of ions onto γ-MnO2 and destabilization of Ag2CO3 in cement environment•Strong decrease of H2 outgassing from mortars encapsulating Al metal