Zn2Mo3O8/ZnMo8O10/Mo8O23 nanocomposites; structural properties, synthesis and its emerging application in electrochemical hydrogen storage.

Electrode materials based on zinc molybdenum oxides were designed by the saccharide-assisted sol-gel procedure for electrochemical hydrogen storage (EHS). By using different characterization methods to observe the formation of nanostructures, it was possible to determine that carbon texture was present on the nanostructured surfaces of zinc molybdenum oxides. The effects of employing various saccharides (mono, di, and poly saccharides) as carbon sources and fuel on the microstructure, electrochemical behaviors, and purity of synthesized samples were compared. The growth of nanocomposites including Zn 2 Mo 3 O 8 , ZnMo 8 O 10 , and Mo 8 O 23 phases was facilitated by the saccharide. A charge-discharge method was used to build three-electrode cells and expose them to galvanostatic cycling. To ascertain the stability of electrode architectures, cycling performance at various rates was carried out. The samples' hydrogen storage capabilities were examined, and the sample generated with glucose showed an optimum capacity about 1017 mAhg−1 after 15th cycle. • Saccharide assisted sol-gel synthesis of carbonous zinc molybdate nanocomposites as electrode materials. • Investigation of crystallinity, microstrain and structural parameters. • The assessment of hydrogen storage activity using comparative chronopotentiometry study. • Understanding of redox and physisorption-based efficient storage mechanisms. [ABSTRACT FROM AUTHOR]