Surface passivation is a general issue for Si-based photoelectrodes because it progressively hinders electron conduction at the semiconductor/electrolyte interface. In this work, we show that a sputtered 100 nm TiO(2) layer on top of a thin Ti metal layer may be used to protect an n(+)p Si photocathode during photocatalytic H(2) evolution. Although TiO(2) is a semiconductor, we show that it behaves like a metallic conductor would under photocathodic H(2) evolution conditions. This behavior is due to the fortunate alignment of the TiO(2) conduction band with respect to the hydrogen evolution potential, which allows it to conduct electrons from the Si while simultaneously protecting the Si from surface passivation. By using a Pt catalyst the electrode achieves an H(2) evolution onset of 520 mV vs NHE and a Tafel slope of 30 mV when illuminated by the red part (λ > 635 nm) of the AM 1.5 spectrum. The saturation photocurrent (H(2) evolution) was also significantly enhanced by the antireflective properties of the TiO(2) layer. It was shown that with proper annealing conditions these electrodes could run 72 h without significant degradation. An Fe(2+)/Fe(3+) redox couple was used to help elucidate details of the band diagram.
Brought to light: Thin, planar nanojunctions between layered MoS2 and graphitic CN (g‐CN) were constructed and allowed fast charge separation across the junction interfaces to facilitate hydrogen photosynthesis. This research represents a proof of concept for the rational fabrication of thin interfacial junctions between co‐catalysts and semiconductors having similar layered geometric structures.
Crystalline Ni5P4 evolves hydrogen with electrical-efficiency comparable to platinum—while being corrosion-resistant in both acid and base for >16 hours.
A low-cost substitute: A titanium protection layer on silicon made it possible to use silicon under highly oxidizing conditions without oxidation of the silicon. Molybdenum sulfide was electrodeposited on the Ti-protected n(+)p-silicon electrode. This electrode was applied as a photocathode for water splitting and showed a greatly enhanced efficiency.
The electrochemical hydrogen evolution reaction (HER) is growing in significance as society begins to rely more on renewable energy sources such as wind and solar power. Thus, research on designing new, inexpensive, and abundant HER catalysts is important. Here, we describe how a simple experiment combined with results from density functional theory (DFT) can be used to introduce the Sabatier principle and its importance when designing new catalysts for the HER. We also describe the difference between reactivity and catalytic activity of solid surfaces and explain how DFT is used to predict new catalysts based on this. Suited for upper-level high school and first-year university students, this exercise involves using a basic two-cell electrochemical setup to test multiple electrode materials as catalysts at one applied potential, and then constructing a volcano curve with the resulting currents. The curve visually shows students that the best HER catalysts are characterized by an optimal hydrogen binding energy (reactivity), as stated by the Sabatier principle. In addition, students may use this volcano curve to predict the activity of an untested catalyst solely from the catalyst reactivity. This exercise circumvents the complexity of traditional experiments while it still demonstrates the trends of the HER volcano known from literature.
We
report microcrystalline Ni3P as a noble-metal-free
electrocatalyst for the H2 evolution reaction (HER) with
high activity just below those of Ni5P4 and
Pt, the two most efficient HER catalysts known. Ni3P has
previously been dismissed for the HER, owing to its anticipated corrosion
and its low activity when formed as an impurity in amorphous alloys.
We observe higher activity of single-phase Ni3P crystallites
than for other nickel phosphides (except Ni5P4) in acid, high corrosion tolerance in acid, and zero corrosion in
alkali. We compare its electrocatalytic performance, corrosion stability,
and intrinsic turnover rate to those of different transition-metal
phosphides. Electrochemical studies reveal that poisoning of surface
Ni sites does not block the HER, indicating P as the active site.
Using density functional theory (DFT), we analyze the thermodynamic
stability of Ni3P and compare it to experiments. DFT calculations
predict that surface reconstruction of Ni3P (001) strongly
favors P enrichment of the Ni4P4 termination
and that the H adsorption energy depends strongly on the surface reconstruction,
thus revealing a potential synthetic lever for tuning HER catalytic
activity. A particular P-enriched reconstructed surface on Ni3P(001) is predicted to be the most stable surface termination
at intermediate P content, as well as providing the most active surface
site at low overpotentials. The P adatoms present on this reconstructed
surface are more active for HER at low overpotentials in comparison
to any of the sites investigated on other terminations of Ni3P(001), as they possess nearly thermoneutral H adsorption. To our
knowledge this is the first time reconstructed surfaces of transition-metal
phosphides have been identified as having the most active surface
site, with such good agreement with the experimentally observed catalytic
current onset and Tafel slope. The active site geometry achieved through
reconstruction identified in this work shows great similarity to that
reported for Ni2P(0001) and Ni5P4(0001) facets, serving as a general design principle for the future
development of even more active transition-metal phosphide catalysts
and further climbing the volcano plot.
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