Fig. 1. Synthesis and structure characterizations. (a) Schematic process for synthesizing Ni/VOx. SEM (b), TEM (c) and HRTEM (d) images of Ni/V2O3 catalyst. (e) HAADF image and EDS elemental mappings of Ni/V2O3 catalyst.

Fig. 2. Chemical state and electronic structure characterizations. High resolution XPS spectra of Ni 2p (a), V 2p (b), and O 1s (c) for NF@Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5. XANES spectra of the Ni K-edge (d) and average valence state (e) of Ni in Ni/V2O3, Ni/VO2 and Ni/V2O5. EXAFS spectra of the Ni K-edge (f) and wavelet-transform plots (g) for the Ni, NiO, Ni/V2O3, Ni/VO2 and Ni/V2O5.

Fig. 3. Electrocatalytic HER performances. Polarization curves (a), overpotentials at 500 and 1000 mA cm-2 (b), and Tafel curves (c) of NF@Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5 in 1 mol L?1 KOH. Polarization curves (d), overpotentials at 500 and 1000 mA cm-2 (e), and Tafel curves (f) of NF@Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5 in 1 mol L?1 KOH + seawater. Comparison of overpotentials at 100 mA cm-2 (η100) and Tafel slopes between Ni/V2O3 and reported catalysts in 1 mol L?1 KOH (g) and 1 mol L?1 KOH + seawater (h). (i) Chronopotentiometry curves of NF@Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5 electrodes in 1 mol L?1 KOH and 1 mol L?1 KOH + seawater.

Fig. 4. In-situ impedance and interfacial water behavior. Bode plots of the in-situ electrochemical impedance spectra of NF@Ni (a), Ni/V2O3 (b), Ni/VO2 (c), and Ni/V2O5 (d) in 1 mol L-1 KOH. In-situ FTIR contour plots and spectra of interfacial water at surface of NF@Ni (e,i), Ni/V2O3 (f,j), Ni/VO2 (g,k), and Ni/V2O5 (h,l) under different potentials in 0.1 mol L-1 KOH. The proportion of 2-HB·H2O (m), 4-HB·H2O (n) and free-H2O (o) on surface of NF@Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5. (p) PZC values of NF@Ni, Ni/V2O3, Ni/VO2, and Ni/V2O5.

Fig. 5. DFT calculations. (a) The structure and differential charge density of Ni/V2O3, Ni/VO2 and Ni/V2O5. (b) Partial density of state analysis and d-band centers for Ni, Ni/V2O3, Ni/VO2, and Ni/V2O5. (c) Calculated adsorption energy of H2O* (EH2O*) and OH* (EOH*) on Ni, Ni/V2O3, Ni/VO2 and Ni/V2O5. (d) Calculated hydrogen adsorption free energy on the Ni, Ni/V2O3, Ni/VO2, and Ni/V2O5. (e) Alkaline HER process on Ni/V2O3. (f) Schematic illustration of the interfacial water structure and HER process on Ni/V2O3 in seawater. (g) Relationships among calculated ΔGH*, PZC values, Ni valence, conversion rate of free-H2O, and overpotentials at 500 mA cm?2 for Ni, Ni/V2O3, Ni/VO2, and Ni/V2O5.

Fig. 6. Large-area Ni/V2O3 electrode production and uniformity characterizations. (a) Optical image of the Ni/V2O3 electrode with a geometric area of approximately 50 cm2. (b?h) SEM images of Ni/V2O3 in the selected regions in (a). LSV curves and corresponding overpotentials for the HER of the selected region of Ni/V2O3 in alkaline freshwater (i,l), alkaline seawater (j,m), and natural seawater (k,n).

Fig. 7. Performances of the kW-scale three-cell ASWE stack with Ni/V2O3 || NiFe-LDH electrodes. (a) Component and structure of one ASWE cell. (b, c) Digital images of the three-cell ASWE stack. Polarization curve (d) and Nyquist plot (e) of the three-cell ASWE stack in 6 mol L-1 KOH + seawater at 60 °C. (f) Durability and energy consumption of the three-cell ASWE stack at 25 A (0.5 A cm-2) in 6 mol L-1 KOH + seawater at 60 °C.