Increasing
demand for finding eco-friendly and everlasting energy
sources is now totally depending on fuel cell technology. Though it
is an eco-friendly way of producing energy for the urgent requirements,
it needs to be improved to make it cheaper and more eco-friendly.
Although there are several types of fuel cells, the hydrogen (H2) and oxygen (O2) fuel cell is the one with zero
carbon emission and water as the only byproduct. However, supplying
fuels in the purest form (at least the H2) is essential
to ensure higher life cycles and less decay in cell efficiency. The
current large-scale H2 production is largely dependent
on steam reforming of fossil fuels, which generates CO2 along with H2 and the source of which is going to be
depleted. As an alternate, electrolysis of water has been given greater
attention than the steam reforming. The reasons are as follows: the
very high purity of the H2 produced, the abundant source,
no need for high-temperature, high-pressure reactors, and so on. In
earlier days, noble metals such as Pt (cathode) and Ir and Ru (anode)
were used for this purpose. However, there are problems in employing
these metals, as they are noble and expensive. In this review, we
elaborate how the group VIII 3d metal sulfide, selenide, and phosphide
nanomaterials have arisen as abundant and cheaper electrode materials
(catalysts) beyond the oxides and hydroxides of the same. We also
highlight the evaluation perspective of such electrocatalysts toward
water electrolysis in detail.
A highly stable Re0 organosol on a DNA scaffold has been synthesized for the first time and tested for two different potential applications such as in the catalytic reduction of hexavalent chromium ions and in SERS studies.
Size and shape-selective Sn(MoO4)2 nanomaterials have been synthesized for the first time using a simple hydrothermal route by the reaction of Sn(ii) chloride salt with sodium molybdate in CTAB micellar media under stirring at 60 °C temperature for about three hours. Needle-like and flake-like Sn(MoO4)2 nanomaterials were synthesized by optimizing the CTAB to metal salt molar ratio and by controlling other reaction parameters. The eventual diameter and length of the nanoneedles are ∼100 ± 10 nm and ∼850 ± 100 nm respectively. The average diameter of the flakes is ∼250 ± 50 nm. The synthesized Sn(MoO4)2 nanomaterials can be used in two potential applications, namely, catalytic reduction of nitroarenes and as an anodic material in electrochemical supercapacitors. From the catalysis study, it was observed that the Sn(MoO4)2 nanomaterials could act as a potential catalyst for the successful photochemical reduction of nitroarenes into their respective aminoarenes within a short reaction time. From the supercapacitor study, it was observed that the Sn(MoO4)2 nanomaterials of different shapes show different specific capacitance (Cs) values and the highest Cs value was observed for Sn(MoO4)2 nanomaterials having a flake-like morphology. The highest Cs value observed was 109 F g(-1) at a scan rate of 5 mV s(-1) for the flake-like Sn(MoO4)2 nanomaterials. The capacitor shows an excellent long cycle life along with 70% retention of the Cs value, even after 4000 consecutive cycles at a current density of 8 mA cm(-2). Other than the applications in catalysis and supercapacitors, the synthesized nanomaterials can find further applications in photoluminescence, sensor and other energy-related devices.
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