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Seawater Splitting for Hydrogen Generation Using Zirconium and Its Niobium Alloy under Gamma Radiation.

Imran AliGunel T ImanovaTeymur AgayevAnar AliyevSakin JabarovHassan M AlbishriWael Hamad AlshitariAhmed M HameedAhmed M Hameed
Published in: Molecules (Basel, Switzerland) (2022)
Hydrogen production is produced for future green energy. The radiation-chemical yield for seawater without a catalyst, with Zr, and with Zr1%Nb (Zr = 99% Nb = 1%) were (G(H 2 ) = 0.81, 307.1, and 437.4 molecules/100 eV, respectively. The radiation-thermal water decomposition increased in γ-radiation of the Zr1%Nb + SW system with increasing temperature. At T = 1273 K, it prevails over radiation processes. During the radiation and heat radiation heterogeneous procedures in the Zr1% Nb + SW system, the production of surface energetic sites and secondary electrons accelerated the accumulation of molecular hydrogen and Zr1%Nb oxidation. Thermal radiation and thermal processes caused the metal phase to collect thermal surface energetic sites for water breakdown and Zr 1%Nb oxidation starting at T = 573 K.
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