Oxygen reduction reaction (ORR) is increasingly being studied in oxide systems due to advantages ranging from cost effectiveness to desirable kinetics. Oxygen-deficient oxides like brownmillerites are known to enhance ORR activity by providing oxygen adsorption sites. In parallel, nitrogen and iron doping in carbon materials, and consequent presence of catalytically active complex species like C-Fe-N, is also suggested to be good strategies for designing ORR-active catalysts. A combination of these features in N-doped Fe containing brownmillerite can be envisaged to present synergistic effects to improve the activity. This is conceptualized in this report through enhanced activity of N-doped CaFeO brownmillerite when compared to its oxide parents. N doping is demonstrated by neutron diffraction, UV-vis spectroscopy, X-ray photoelectron spectroscopy, and X-ray absorption spectroscopy. Electrical conductivity is also found to be enhanced by N doping, which influences the activity. Electrochemical characterization by cyclic voltammetry, rotating disc electrode, and rotating ring disk electrode (RRDE) indicates an improved oxygen reduction activity in N-doped brownmillerite, with a 10 mV positive shift in the onset potential. RRDE measurements show that the compound exhibits 4-electron reduction pathways with lower HO production in the N-doped system; also, the N-doped sample exhibited better stability. The observations will enable better design of ORR catalysts that are stable and cost-effective.
Herein, we report the synthesis of a nitrogen-doped graphene (NGr) interpenetrated 3D Ni-nanocage (Ni-NGr) electrocatalyst by a simple water-in-oil (w/o) emulsion technique for oxidation of water to dioxygen. Correlation of adsorption of NGr and subsequent interpenetration through the specific surface plane of nickel particles as well as the concomitant interaction of N and C with Ni in the nano-regime has been investigated. Apart from the benefits of the synergistic interactions between Ni, N, and C, the overall integrity of the structure and its intra-molecular connectivity within the framework help in achieving better oxygen evolution characteristics at a significantly reduced overpotential. The engineered Ni-NGr nanocage displays a substantially low overpotential of ∼290 mV at a practical current density of 20 mA cm(-2) in 0.1 M KOH. In comparison, NGr and Ni-particles as separate entities give overpotentials of ∼570 and ∼370 mV under similar conditions. Moreover, the long term stability of Ni-NGr was investigated by anodic potential cycling for 500 cycles and an 8.5% increment in the overpotential at 20 mA cm(-2) was observed. Additionally, a chronoamperometric test was performed for 15 h at 20 mA cm(-2), which highlights the better sustainability of Ni-NGr under the actual operating conditions. Finally, the quantitative estimation of evolved oxygen was monitored by gas chromatography and was found to be 70 mmol h(-1) g(-1) of oxygen, which is constant in the second cycle as well.
A disordered brownmillerite, Ba 2 InCeO 5+δ , with slight tetragonal distortion from ideal cubic perovskite is synthesized and its oxygen reduction reactivity tested. The material displayed oxygen reduction behavior in alkaline solution comparable to that of standard 40 wt % Pt/C catalyst and attractive activity characteristics which renders it a potential system for low temperature fuel cell applications.
Precious metal incorporated into stable lattices like perovskites can be envisaged as an alternative catalysts to address deactivation problems. Here we report the barium cerate perovskite doped with varying amounts of Pt as catalysts for the water−gas shift reaction whereby ionic Pt is evidenced to be active. It is found that maximum CO conversion occurs above 325 °C and increases more than 2-fold after the first cycle. XPS analysis shows that after the first cycle, more ionic Pt species are present on the surface of the catalyst. X-ray and neutron diffraction studies also indicate the presence of oxygen vacancies that increases with increasing Pt substitution.
Electrocatalytic
oxidation of simple organic molecules offers a
promising strategy to combat the sluggish kinetics of the water oxidation
reaction (WOR). The low potential requirement, inhibition of the crossover
of gases, and formation of value-added products at the anode are benefits
of the electrocatalytic oxidation of organic molecules. Herein, we
developed cobalt–nickel-based layered double hydroxide (LDH)
as a robust material for the electrocatalytic oxidation of alcohols
and urea at the anode, replacing the WOR. A facile synthesis protocol
to form LDHs with different ratios of Co and Ni is adapted. It demonstrates
that the reactants could be efficiently oxidized to concomitant chemical
products at the anode. The half-cell study shows an onset potential
of 1.30 V for benzyl alcohol oxidation reaction (BAOR), 1.36 V for
glycerol oxidation reaction (GOR), 1.33 V for ethanol oxidation reaction
(EOR), and 1.32 V for urea oxidation reaction (UOR) compared with
1.53 V for WOR. Notably, the hybrid electrolyzer in a full-cell configuration
significantly reduces the overall cell voltage at a 20 mA cm–2 current density by ∼15% while coupling with the BAOR, EOR,
and GOR and ∼12% with the UOR as the anodic half-cell reaction.
Furthermore, the efficiency of hydrogen generation remains unhampered
with the types of oxidation reactions (alcohols and urea) occurring
at the anode. This work demonstrates the prospects of lowering the
overall cell voltage in the case of a water electrolyzer by integrating
the hydrogen evolution reaction with suitable organic molecule oxidation.
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