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

Ali, Imran; İmanova, Günel; Agayev, Teymur; Aliyev, Anar; Jabarov, Sakin; Albishri, Hassan; Alshitari, Wael; Hameed, Ahmed; Alharbi, Ahmed

doi:10.3390/molecules27196325

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

Ali I., İmanova G., Agayev T., Aliyev A., Jabarov S., Albishri H. M., ...daha çox

Molecules, vol.27, no.19, 2022 (SCI-Expanded, Scopus)

Nəşrin Növü: Article / Article
Cild: 27 Say: 19
Nəşr tarixi: 2022
Doi nömrəsi: 10.3390/molecules27196325
jurnalın adı: Molecules
Jurnalın baxıldığı indekslər: Science Citation Index Expanded (SCI-EXPANDED), Scopus, Academic Search Premier, Aerospace Database, Biotechnology Research Abstracts, CAB Abstracts, Chemical Abstracts Core, Communication Abstracts, EMBASE, Food Science & Technology Abstracts, MEDLINE, Metadex, Veterinary Science Database, Directory of Open Access Journals, Civil Engineering Abstracts
Açar sözlər: hydrogen generation, seawater splitting, thermal and radiation–thermal decompositions, Zr1%Nb alloys, γ-radiation
Adres: Bəli

Qısa məlumat

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(H2) = 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.