An oxygen evolution catalyst that forms as a thin film from Ni(aq)(2+) solutions containing borate electrolyte (Ni-B(i)) has been studied by in situ X-ray absorption spectroscopy. A dramatic increase in catalytic rate, induced by anodic activation of the electrodeposited films, is accompanied by structure and oxidation state changes. Coulometric measurements correlated with X-ray absorption near-edge structure spectra of the active catalyst show that the nickel centers in activated films possess an average oxidation state of +3.6, indicating that a substantial proportion of nickel centers exist in a formal oxidation state of Ni(IV). In contrast, nickel centers in nonactivated films exist predominantly as Ni(III). Extended X-ray absorption fine structure reveals that activated catalyst films comprise bis-oxo/hydroxo-bridged nickel centers organized into sheets of edge-sharing NiO(6) octahedra. Diminished long-range ordering in catalyst films is due to their ostensibly amorphous nature. Nonactivated films display a similar oxidic nature but exhibit a distortion in the local coordination geometry about nickel centers, characteristic of Jahn-Teller distorted Ni(III) centers. Our findings indicate that the increase in catalytic activity of films is accompanied by changes in oxidation state and structure that are reminiscent of those observed for conversion of β-NiOOH to γ-NiOOH and consequently challenge the long-held notion that the β-NiOOH phase is a more efficient oxygen-evolving catalyst.
In-situ x-ray absorption spectroscopy (XAS) is a powerful technique that can be applied to electrochemical systems, with the ability to elucidate the chemical nature of electrocatalysts under reaction conditions. In this study, we perform in-situ XAS measurements on a bifunctional manganese oxide (MnOx) catalyst with high electrochemical activity for the oxygen reduction reaction (ORR) and the oxygen evolution reaction (OER). Using x-ray absorption near edge structure (XANES) and extended x-ray absorption fine structure (EXAFS), we find that exposure to an ORR-relevant potential of 0.7 V vs. RHE produces a disordered Mn3II,III,IIIO4 phase with negligible contributions from other phases. After the potential is increased to a highly anodic value of 1.8 V vs. RHE, relevant to the OER, we observe an oxidation of approximately 80% of the catalytic thin film to form a mixed MnIII,IV oxide, while the remaining 20% of the film consists of a less oxidized phase, likely corresponding to unchanged Mn3II,III,IIIO4. XAS and electrochemical characterization of two thin film catalysts with different MnOx thicknesses reveals no significant influence of thickness on the measured oxidation states, at either ORR or OER potentials, but demonstrates that the OER activity scales with film thickness. This result suggests that the films have porous structure, which does not restrict electrocatalysis to the top geometric layer of the film. As the portion of the catalyst film that is most likely to be oxidized at the high potentials necessary for the OER is that which is closest to the electrolyte interface, we hypothesize that the MnIII,IV oxide, rather than Mn3II,III,IIIO4, is the phase pertinent to the observed OER activity.
Intense femtosecond X-ray pulses produced at the Linac Coherent Light Source (LCLS) were used for simultaneous X-ray diffraction (XRD) and X-ray emission spectroscopy (XES) of microcrystals of Photosystem II (PS II) at room temperature. This method probes the overall protein structure and the electronic structure of the Mn4CaO5 cluster in the oxygen-evolving complex of PS II. XRD data are presented from both the dark state (S1) and the first illuminated state (S2) of PS II. Our simultaneous XRD/XES study shows that the PS II crystals are intact during our measurements at the LCLS, not only with respect to the structure of PS II, but also with regard to the electronic structure of the highly radiation sensitive Mn4CaO5 cluster, opening new directions for future dynamics studies.
The oxygen evolution
reaction (OER) is a key process that enables
the storage of renewable energies in the form of chemical fuels. Here,
we describe a catalyst that exhibits turnover frequencies higher than
state-of-the-art catalysts that operate in alkaline solutions, including
the benchmark nickel iron oxide. This new catalyst is easily prepared
from readily available and industrially relevant nickel foam, and
it is stable for many hours. Operando X-ray absorption spectroscopic
data reveal that the catalyst is made of nanoclusters of γ-FeOOH
covalently linked to a γ-NiOOH support. According to density
functional theory (DFT) computations, this structure may allow a reaction
path involving iron as the oxygen evolving center and a nearby terrace
O site on the γ-NiOOH support oxide as a hydrogen acceptor.
Molecular catalysts that combine high product selectivity and high current density for CO
2
electrochemical reduction to CO or other chemical feedstocks are urgently needed. While earth-abundant metal-based molecular electrocatalysts with high selectivity for CO
2
to CO conversion are known, they are characterized by current densities that are significantly lower than those obtained with solid-state metal materials. Here, we report that a cobalt phthalocyanine bearing a trimethyl ammonium group appended to the phthalocyanine macrocycle is capable of reducing CO
2
to CO in water with high activity over a broad pH range from 4 to 14. In a flow cell configuration operating in basic conditions, CO production occurs with excellent selectivity (ca. 95%), and good stability with a maximum partial current density of 165 mA cm
−2
(at −0.92 V vs. RHE), matching the most active noble metal-based nanocatalysts. These results represent state-of-the-art performance for electrolytic carbon dioxide reduction by a molecular catalyst.
The
reduction of protons into dihydrogen is important because of
its potential use in a wide range of energy applications. The preparation
of efficient and cheap catalysts for this reaction is one of the issues
that need to be tackled to allow the widespread use of hydrogen as
an energy carrier. In this paper, we report the study of an amorphous
molybdenum sulfide (MoSx) proton reducing
electrocatalyst under functional conditions, using in situ X-ray absorption spectroscopy. We probed the local and electronic
structures of both the molybdenum and sulfur elements for the as prepared
material as well as the precatalytic and catalytic states. The as
prepared material is very similar to MoS3 and remains unmodified
under functional conditions (pH = 2 aqueous HNO3) in the
precatalytic state (+0.3 V vs RHE). In its catalytic state (−0.3
V vs RHE), the film is reduced to an amorphous form of MoS2 and shows spectroscopic features that indicate the presence of terminal
disulfide units. These units are formed concomitantly with the release
of hydrogen, and we suggest that the rate-limiting step of the HER
is the reduction and protonation of these disulfide units. These results
show the implication of terminal disulfide chemical motifs into HER
driven by transition-metal sulfides and provide insight into their
reaction mechanism.
The sandwich-type polyoxometalate (POM) [(PWO)Co(HO)] was immobilized in the hexagonal channels of the Zr(IV) porphyrinic MOF-545 hybrid framework. The resulting composite was fully characterized by a panel of physicochemical techniques. Calculations allowed identifying the localization of the POM in the vicinity of the Zr clusters and porphyrin linkers constituting the MOF. The material exhibits a high photocatalytic activity and good stability for visible-light-driven water oxidation. It thus represents a rare example of an all-in-one fully noble metal-free supramolecular heterogeneous photocatalytic system, with the catalyst and the photosensitizer within the same porous solid material.
X-ray free-electron laser (XFEL) sources enable the use of crystallography to
solve three-dimensional macromolecular structures under native conditions and free from
radiation damage. Results to date, however, have been limited by the challenge of deriving
accurate Bragg intensities from a heterogeneous population of microcrystals, while at the
same time modeling the X-ray spectrum and detector geometry. Here we present a
computational approach designed to extract statistically significant high-resolution
signals from fewer diffraction measurements.
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