Nanoparticles of cobalt phosphide, CoP, have been prepared and evaluated as electrocatalysts for the hydrogen evolution reaction (HER) under strongly acidic conditions (0.50 M H2SO4, pH 0.3). Uniform, multi-faceted CoP nanoparticles were synthesized by reacting Co nanoparticles with trioctylphosphine. Electrodes comprised of CoP nanoparticles on a Ti support (2 mg cm(-2) mass loading) produced a cathodic current density of 20 mA cm(-2) at an overpotential of -85 mV. The CoP/Ti electrodes were stable over 24 h of sustained hydrogen production in 0.50 M H2SO4. The activity was essentially unchanged after 400 cyclic voltammetric sweeps, suggesting long-term viability under operating conditions. CoP is therefore amongst the most active, acid-stable, earth-abundant HER electrocatalysts reported to date.
Hydrogen gas obtained by the electrolysis
of water has long been
proposed as a clean and sustainable alternative to fossil fuels. Noble
metals such as Pt are capable of splitting water at low overpotentials,
but the implementation of inexpensive solar-driven water-splitting
systems and electrolyzers could benefit from the development of robust,
efficient, and abundant alternatives to noble metal catalysts. Transition
metal phosphides (M
x
P
y
) have recently been identified as a promising family of Earth
abundant electrocatalysts for the hydrogen-evolution reaction (HER)
and are capable of operating with low overpotentials at operationally
relevant current densities while exhibiting stability under strongly
acidic conditions. In this review, we highlight the progress that
has been made in this field and provide insights into the synthesis,
characterization, and electrochemical behavior of transition metal
phosphides as HER electrocatalysts. We also discuss strategies for
the incorporation of metal phosphides into integrated solar-driven
water-splitting systems and highlight key considerations involved
in the testing and benchmarking of such devices.
Nanoparticles of cobalt phosphide, CoP, have been prepared and evaluated as electrocatalysts for the hydrogen evolution reaction (HER) under strongly acidic conditions (0.50 M H2SO4, pH 0.3). Uniform, multi‐faceted CoP nanoparticles were synthesized by reacting Co nanoparticles with trioctylphosphine. Electrodes comprised of CoP nanoparticles on a Ti support (2 mg cm−2 mass loading) produced a cathodic current density of 20 mA cm−2 at an overpotential of −85 mV. The CoP/Ti electrodes were stable over 24 h of sustained hydrogen production in 0.50 M H2SO4. The activity was essentially unchanged after 400 cyclic voltammetric sweeps, suggesting long‐term viability under operating conditions. CoP is therefore amongst the most active, acid‐stable, earth‐abundant HER electrocatalysts reported to date.
The electrical transport in amorphous titanium dioxide (a-TiO 2 ) thin films deposited by atomic-layer deposition (ALD), and across heterojunctions of p + -Si|a-TiO 2 |metal substrates that had various top metal contacts, has been characterized by AC conductivity, temperaturedependent DC conductivity, space-charge-limited current (SCLC) spectroscopy, electron paramagnetic resonance (EPR), X-ray photoelectron spectroscopy (XPS), and current density versus voltage (J-V) characteristics. Amorphous TiO 2 films were fabricated using either tetrakis(dimethylamido)-titanium (TDMAT) with a substrate temperature of 150 °C or TiCl 4 with a substrate temperature of 50, 100, or 150 °C. EPR spectroscopy of the films showed that the Ti 3+ concentration varied with the deposition conditions, and increases in the concentration of Ti 3+ in the films correlated with increases in film conductivity. Valence-band spectra for the a-TiO 2 films exhibited a defect-state peak below the conduction-band minimum (CBM), and increases in the intensity of this peak correlated with increases in the Ti 3+ concentration measured by EPR as well as with increases in film conductivity. The temperature dependent conduction data showed Arrhenius behavior at room temperature with an activation energy that decreased with decreasing temperature, suggesting that conduction did not occur primarily through either the valence or conduction bands. The data from all of the measurements are consistent with a Ti 3+ defect-mediated transport mode involving a hopping mechanism with a
CoP nanostructures that exposed predominantly (111) crystal facets were synthesized and evaluated for performance as electrocatalysts for the hydrogen-evolution reaction (
The electrocatalytic performance for hydrogen evolution has been evaluated for radial-junction n + p-Si microwire (MW) arrays with Pt or cobalt phosphide, CoP, nanoparticulate catalysts in contact with 0.50 M H 2 SO 4 (aq). The CoP-coated (2.0 mg cm −2 ) n + p-Si MW photocathodes were stable for over 12 h of continuous operation and produced an open-circuit photovoltage (V oc ) of 0.48 V, a light-limited photocurrent density (J ph ) of 17 mA cm −2 , a fill factor (ff) of 0.24, and an ideal regenerative cell efficiency (η IRC ) of 1.9% under simulated 1 Sun illumination. Pt-coated (0.5 mg cm −2 ) n + p-Si MW-array photocathodes produced V oc = 0.44 V, J ph = 14 mA cm −2 , ff = 0.46, and η = 2.9% under identical conditions. Thus, the MW geometry allows the fabrication of photocathodes entirely comprised of earth-abundant materials that exhibit performance comparable to that of devices that contain Pt.
The average oxide thickness was measured using quantitative XPS and AFM was not used for thickness measurements. The oxide coverage on the Si surfaces was calculated according to published methods using the following equations:where ߔ is the fractional coverage of monolayer A over the substrate B.
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