20 research outputs found
A Half-Reaction Alternative to Water Oxidation: Chloride Oxidation to Chlorine Catalyzed by Silver Ion
Chloride oxidation to chlorine is
a potential alternative to water
oxidation to oxygen as a solar fuels half-reaction. AgĀ(I) is potentially
an oxidative catalyst but is inhibited by the high potentials for
accessing the AgĀ(II/I) and AgĀ(III/II) couples. We report here that
the complex ions AgCl<sub>2</sub><sup>ā</sup> and AgCl<sub>3</sub><sup>2ā</sup> form in concentrated Cl<sup>ā</sup> solutions, avoiding AgCl precipitation and providing access to the
higher oxidation states by delocalizing the oxidative charge over
the Cl<sup>ā</sup> ligands. Catalysis is homogeneous and occurs
at high rates and low overpotentials (10 mV at the onset) with Ī¼M
AgĀ(I). Catalysis is enhanced in D<sub>2</sub>O as solvent, with a
significant H<sub>2</sub>O/D<sub>2</sub>O inverse kinetic isotope
effect of 0.25. The results of computational studies suggest that
Cl<sup>ā</sup> oxidation occurs by 1e<sup>ā</sup> oxidation
of AgCl<sub>3</sub><sup>2ā</sup> to AgCl<sub>3</sub><sup>ā</sup> at a decreased potential, followed by Cl<sup>ā</sup> coordination,
presumably to form AgCl<sub>4</sub><sup>2ā</sup> as an intermediate.
Adding a second Cl<sup>ā</sup> results in āredox potential
levelingā, with further oxidation to {AgCl<sub>2</sub>(Cl<sub>2</sub>)}<sup>ā</sup> followed by Cl<sub>2</sub> release
Hierarchically Structured CuCo<sub>2</sub>S<sub>4</sub> Nanowire Arrays as Efficient Bifunctional Electrocatalyst for Overall Water Splitting
Hydrogen
produced from water splitting offers a green alternative to conventional
energy such as fossil fuels. Herein, CuCo<sub>2</sub>S<sub>4</sub> nanowire arrays were synthesized on a nickel foam substrate by a
two-step hydrothermal approach and utilized as highly efficient bifunctional
electrocatalyst for overall water splitting. The CuCo<sub>2</sub>S<sub>4</sub> nanowire arrays were identified as an exceptionally active
catalyst for the hydrogen evolution reaction (HER) in a basic solution
with an extremely low overpotential of 65 mV to reach a current density
of 10 mA/cm<sup>2</sup>. The hierarchically structured CuCo<sub>2</sub>S<sub>4</sub> electrode was also highly active toward the oxygen
evolution reaction (OER), achieving a high current density of 100
mA/cm<sup>2</sup> at an overpotential of only 310 mV. Consequently,
an alkaline electrolyzer constructed using CuCo<sub>2</sub>S<sub>4</sub> nanowire arrays as both anode and cathode can realize overall water
splitting with a current density of 100 mA/cm<sup>2</sup> at a cell
voltage of 1.65 V, suggesting a promising bifunctional electrocatalyst
for efficient overall water splitting
Cs(I) Cation Enhanced Cu(II) Catalysis of Water Oxidation
We report here a
new catalytic water oxidation system based on CuĀ(II) ions and a remarkable
countercation effect on the catalysis. In a concentrated fluoride
solution at neutral to weakly basic pHs, simple CuĀ(II) salts are highly
active and robust in catalyzing water oxidation homogeneously. F<sup>ā</sup> in solution acts as a proton acceptor and an oxidatively
robust ligand. F<sup>ā</sup> coordination prevents precipitation
of CuĀ(II) as CuF<sub>2</sub>/CuĀ(OH)<sub>2</sub> and lowers potentials
for accessing high-oxidation-state Cu by delocalizing the oxidative
charge over F<sup>ā</sup> ligands. Significantly, the catalytic
current is greatly enhanced in a solution of CsF compared to those
of KF and NaF. Although countercations are not directly involved in
the catalytic redox cycle, UVāvis and <sup>19</sup>F nuclear
magnetic resonance measurements reveal that coordination of F<sup>ā</sup> to CuĀ(II) is dependent on countercations by Coulombic
interaction. A less intense interaction between F<sup>ā</sup> and well-solvated Cs<sup>+</sup> as compared with Na<sup>+</sup> and K<sup>+</sup> leads to a more intense coordination of F<sup>ā</sup> to CuĀ(II), which accounts for the improved catalytic
performance
Electrocatalytic Water Oxidation with a Copper(II) Polypeptide Complex
A self-assembly-formed triĀglycylĀglycine macroĀcyclic
ligand (TGG<sup>4ā</sup>) complex of CuĀ(II), [(TGG<sup>4ā</sup>)ĀCu<sup>II</sup>āOH<sub>2</sub>]<sup>2ā</sup>, efficiently
catalyzes water oxidation in a phosphate buffer at pH 11 at room temperature
by a well-defined mechanism. In the mechanism, initial oxidation to
CuĀ(III) is followed by further oxidation to a formal āCuĀ(IV)ā
with formation of a peroxide intermediate, which undergoes further
oxidation to release oxygen and close the catalytic cycle. The catalyst
exhibits high stability and activity toward water oxidation under
these conditions with a high turnover frequency of 33 s<sup>ā1</sup>
Nonaqueous Electrocatalytic Oxidation of the Alkylaromatic Ethylbenzene by a Surface Bound Ru<sup>V</sup>(O) Catalyst
The catalyst [RuĀ(Mebimpy)Ā(4,4ā²-((HO)<sub>2</sub>OPCH<sub>2</sub>)<sub>2</sub>bpyĀ(OH<sub>2</sub>)]<sup>2+</sup>, where
Mebimpy
is 2,6-bisĀ(1-methylbenzimidazol-2-yl)Āpyridine and 4,4ā²-((HO)<sub>2</sub>OPCH<sub>2</sub>)<sub>2</sub>bpy is 4,4ā²-bis-methlylenephosphonato-2,2ā²-bipyridine,
attached to nanocrystalline SnĀ(IV)-doped In<sub>2</sub>O<sub>3</sub> (nanoITO) electrodes (nanoITO|Ru<sup>II</sup>āOH<sub>2</sub><sup>2+</sup>) has been utilized for the electrocatalytic oxidation
of the alkylaromatics ethylbenzene, toluene, and cumene in propylene
carbonate/water mixtures. Oxidative activation of the surface site
to nanoITO|Ru<sup>V</sup>(O)<sup>3+</sup> is followed by hydrocarbon
oxidation at the surface with a rate constant of 2.5 Ā± 0.2 M<sup>ā1</sup> s<sup>ā1</sup> (<i>I</i> = 0.1 M
LiClO<sub>4</sub>, <i>T</i> = 23 Ā± 2 Ā°C) for the
oxidation of ethylbenzene. Electrocatalytic oxidation of ethylbenzene
to acetophenone occurs with a faradic efficiency of 95%. H/D kinetic
isotope effects determined for oxidation of ethylbenzene point to
a mechanism involving oxygen atom insertion into a CāH bond
of ethylbenzene followed by further 2e<sup>ā</sup>/2H<sup>+</sup> oxidation to acetophenone
Hierarchically Structured Cu-Based Electrocatalysts with Nanowires Array for Water Splitting
We
report here the fabrication of CuO nanowires and their use as
efficient electrocatalyst for the oxygen evolution reaction (OER)
or as precursor for preparation of Cu<sub>3</sub>P nanowires for the
hydrogen evolution reaction (HER). The surface-bound CuĀ(OH)<sub>2</sub> nanowires are <i>in situ</i> grown on a three-dimensional
copper foam (CF) by anodic treatment, which are then converted to
CuO nanowires by calcination in air. The direct growth of nanowires
from the underlying conductive substrate can eliminate the use of
any conductive agents and binders, which ensures good electrical contact
between the electrocatalyst and the conductive substrate. The hierarchically
nanostructured Cu-based electrode exhibits excellent catalytic performance
toward OER in 1 M KOH solution. Phosphorization of the CuO/CF electrode
generates the Cu<sub>3</sub>P/CF electrode, which can act as an excellent
electrocatalyst for HER in 1 M KOH. An alkaline electrolyzer is constructed
using CuO and Cu<sub>3</sub>P nanowires coated copper foams as anode
and cathode, which can realize overall water splitting with a current
density of 102 mA/cm<sup>2</sup> at an applied cell voltage of 2.2
V
Hierarchically Structured Ni Nanotube Array-Based Integrated Electrodes for Water Splitting
The development of
high-performance nonprecious electrocatalysts
for overall water splitting has attracted increasing attention but
remains a vital challenge. Herein, we report a ZnO-based template
method to fabricate Ni nanotube arrays (NTAs) anchored on nickel foil
for applications in the hydrogen evolution reaction (HER) and oxygen
evolution reaction (OER). On the basis of this precursor electrode,
the three-dimensional NiSe<sub>2</sub> NTAs of unique sandwich-like
coaxial structure have been fabricated by electrodeposition of NiSe<sub>2</sub> on Ni NTAs, which exhibits high performance toward the HER
in both acidic and alkaline media. The method based on Ni NTAs can
be readily extended to fabricate Ni<sub>2</sub>P NTAs by gasāsolid
phosphorization for the HER, and NiFeO<sub><i>x</i></sub> NTAs by anodic codeposition of Ni and Fe for the OER. Consequently,
an alkaline electrolyzer has been constructed using NiFeO<sub><i>x</i></sub> NTAs and NiSe<sub>2</sub> NTAs as anode and cathode,
respectively, which can realize overall water splitting with a current
density of 100 mA cm<sup>ā2</sup> at an overpotential of 510
mV
Real-Time Visualization of Diffusion-Controlled Nanowire Growth in Solution
This Letter shows that copper nanowires
grow through the diffusion-controlled
reduction of dihydroxycopperĀ(I), CuĀ(OH)<sub>2</sub><sup>ā</sup>. A combination of potentiostatic coulometry, UVāvisible spectroscopy,
and thermodynamic calculations was used to determine the species adding
to growing Cu nanowires is CuĀ(OH)<sub>2</sub><sup>ā</sup>.
Cyclic voltammetry was then used to measure the diffusion coefficient
of CuĀ(OH)<sub>2</sub><sup>ā</sup> in the reaction solution.
Given the diameter of a Cu nanowire and the diffusion coefficient
of CuĀ(OH)<sub>2</sub><sup>ā</sup>, we calculated the dependence
of the diffusion-limited growth rate on the concentration of copper
ions to be 26 nm s<sup>ā1</sup> mM<sup>ā1</sup>. Independent
measurements of the nanowire growth rate with dark-field optical microscopy
yielded 24 nm s<sup>ā1</sup> mM<sup>ā1</sup> for the
growth rate dependence on the concentration of copper. Dependence
of the nanowire growth rate on temperature yielded a low activation
energy of 11.5 kJ mol<sup>ā1</sup>, consistent with diffusion-limited
growth
High-Yield and Selective Photoelectrocatalytic Reduction of CO<sub>2</sub> to Formate by Metallic Copper Decorated Co<sub>3</sub>O<sub>4</sub> Nanotube Arrays
Carbon
dioxide (CO<sub>2</sub>) reduction to useful chemicals is
of great significance to global climate and energy supply. In this
study, CO<sub>2</sub> has been photoelectrocatalytically reduced to
formate at metallic Cu nanoparticles (Cu NPs) decorated Co<sub>3</sub>O<sub>4</sub> nanotube arrays (NTs) with high yield and high selectivity
of nearly 100%. Noticeably, up to 6.75 mmolĀ·L<sup>ā1</sup>Ā·cm<sup>ā2</sup> of formate was produced in an 8 h photoelectrochemical
process, representing one of the highest yields among those in the
literature. The results of scanning electron microscopy, transmission
electron microscopy and photoelectrochemical characterization demonstrated
that the enhanced production of formate was attributable to the self-supported
Co<sub>3</sub>O<sub>4</sub> NTs/Co structure and the interface band
structure of Co<sub>3</sub>O<sub>4</sub> NTs and metallic Cu NPs.
Furthermore, a possible two-electron reduction mechanism on the selective
PEC CO<sub>2</sub> reduction to formate at the CuāCo<sub>3</sub>O<sub>4</sub> NTs was explored. The first electron reduction intermediate,
CO<sub>2Ā ads</sub><sup>ā¢ā</sup>, was adsorbed on Cu in the form of CuāO. With the carbon
atom suspended in solution, CO<sub>2Ā ads</sub><sup>ā¢ā</sup> is readily protonated
to form the HCOO<sup>ā</sup> radical. And HCOO<sup>ā</sup> as a product rapidly desorbs from the copper surface with a second
electron transfer to the adsorbed species