Sodium-ion hybrid capacitors are
attracting great attention and
are emerging as promising energy storage devices, with their remarkable
footsteps in energy and power densities. However, the development
of efficient electrode materials that result in a minimum trade-off
between their energy and power densities, and that allow long-term
cycling stability, still remains a challenge for realizing their full
potential as an alternate energy storage system for commercial applications.
Herein, for the first time, we study the sodium-ion intercalation
pseudocapacitance behavior of brown TiO2 nanotubes for
their application as an efficient anode material for Na-ion hybrid
capacitors. We synthesized semicrystalline and crystalline anatase
brown TiO2 nanotubes, aggregated in a flowerlike morphology,
through a hydrothermal route, and performed detailed electrochemical
studies. The kinetic studies reveal that semicrystalline brown TiO2 exhibits a Na-ion intercalation pseudocapacitive behavior
with 57% of capacitive storage at 1.0 mV s–1, whereas
crystalline brown TiO2 is more faradaic in nature. Further,
hybrid Na-ion capacitors are fabricated with brown TiO2 materials as an anode and activated carbon as a cathode, and the
fabricated device showed an excellent electrochemical performance
with a high energy density of ∼68 Wh kg–1 and a high power density of ∼12.5 kW kg–1 and with a good cycling stability up to 10 000 cycles with
∼80% capacitive retention. The obtained results represent a
promising approach toward developing efficient electrodes for hybrid
Na-ion capacitors.
Green and rapid microwave syntheses of 'yellow oxygen rich' (YAT-150) and 'black oxygen vacancy rich' (BAT-150) anatase TiO2 nanoparticles are reported for the first time. YAT-150 was synthesized using only titanium(iv) butoxide and water as precursors. The in situ precursor modification by Mn(ii) acetate switched anatase TiO2 from YAT-150 to BAT-150. The entry of Mn(2+) into the crystal lattice of anatase TiO2 paved the way for peak texturing in the existing peak orientations along with the origin of three new anatase TiO2 peaks in the (103), (213) and (105) directions. The as synthesized ultra-small (∼5 nm) yellow and black anatase TiO2 nanoparticles were found to be two fold and four fold more photoactive than the commercially available photocatalyst Degussa-P25 under sunlight illumination.
Dopant free, solar active ZnO photocatalysts with oxygen vacancy richness were achieved by a solution processing strategy followed by calcination at various temperatures 300, 500, 700, 800, and 900 °C. All the ZnO nanocrystals possessed defective structures with copious surface oxygen vacancies directed toward notable visible light absorption around λ = 480 nm (band gap = 3.05−3.09 eV). The photocatalytic efficiencies of all ZnO samples were systematically examined under sunlight and UV illumination using methylene blue (MB) as a model system. ZnO calcined at 500 and 700 °C demonstrated microrod morphology with band gap energies of 3.08 and 3.09 eV respectively have shown the highest solar photocatalytic activity revealed the synergistic effect between oxygen vacancy and the rod morphology. ZnO calcined at 500 °C, having maximum surface oxygen vacancy sites degraded MB within 10 min whereas the commercial photocatalyst Degussa-P25 has taken 20 min under solar illumination.
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