The distinct beneficial effect of Zn-doping on the OER alkaline activity of Fe-based catalysts points towards an alternative and faster two-site mechanism.
We calculate the diffusion coefficients of persistent random walks on cubic and hypercubic lattices, where the direction of a walker at a given step depends on the memory of one or two previous steps. These results are then applied to study a billiard model, namely a three-dimensional periodic Lorentz gas. The geometry of the model is studied in order to find the regimes in which it exhibits normal diffusion. In this regime, we calculate numerically the transition probabilities between cells to compare the persistent random-walk approximation with simulation results for the diffusion coefficient.Submitted to: J. Phys. A: Math. Theor.
The
electrochemical conversion of carbon dioxide (CO2) to high-value
chemicals is an attractive approach to create an
artificial carbon cycle. Tuning the activity and product selectivity
while maintaining long-term stability, however, remains a significant
challenge. Here, we study a series of Au–Pb bimetallic electrocatalysts
with different Au/Pb interfaces, generating carbon monoxide (CO),
formic acid (HCOOH), and methane (CH4) as CO2 reduction products. The formation of CH4 is significant
because it has only been observed on very few Cu-free electrodes.
The maximum CH4 formation rate of 0.33 mA cm–2 was achieved when the most Au/Pb interfaces were present. In situ
Raman spectroelectrochemical studies confirmed the stability of the
Pb native substoichiometric oxide under the reduction conditions on
the Au–Pb catalyst, which seems to be a major contributor to
CH4 formation. Density functional theory simulations showed
that without Au, the reaction would get stuck on the COOH intermediate,
and without O, the reaction would not evolve further than the CHOH
intermediate. In addition, they confirmed that the Au/Pb bimetallic
interface (together with the subsurface oxygen in the model) possesses
a moderate binding strength for the key intermediates, which is indeed
necessary for the CH4 pathway. Overall, this study demonstrates how bimetallic nanoparticles
can be employed to overcome scaling relations in the CO2 reduction reaction.
Sustainable electrocatalysis of the oxygen evolution reaction (OER) constitutes a major challenge for the realization of green fuels. Oxides based on Ni and Fe in alkaline media have been proposed to avoid using critical raw materials. However, their ill-defined structures under OER conditions make the identification of key descriptors difficult. Here, we have studied FeÀ NiÀ Zn spinel oxides, with a well-defined crystal structure, as a platform to obtain general understanding on the key contributions. The OER reaches maximum performance when: (i) Zn is present in the Spinel structure, (ii) very dense, equimolar 1 : 1 : 1 stoichiometry sites appear on the surface as they allow the formation of oxygen vacancies where Zn favors pushing the electronic density that is pulled by the octahedral Fe and tetrahedral Ni redox pair lowering the overpotential. Our work proves cooperative electronic effects on surface active sites as key to design optimum OER electrocatalysts.
Ab initio molecular dynamics simulations have been performed of a gold-1,4-benzenedithiol (BDT)-gold nanojunction under mechanical stress. For three different pulling rates between 10 and 40 m s(-1), it is found that the nanowire always ruptures between the second and third Au atom from the thiol sulfur. Larger rupture forces and longer extensions are required at higher pulling rates and vice versa. The electrical conductance was calculated along a pulling trajectory using the DFT-NEGF method to study the effect of thermal and stress-induced structural changes on the electrical transport properties. While the mechanically induced stretching of the junction is seen to lower the time-averaged conductance, thermal conformational changes are capable of altering the conductance by one order of magnitude. No single geometric quantity could be identified as the main contributor to the conductance fluctuations. Small modulations, however, can be explained in terms of C=C double bond vibrations in the BDT molecule. The dependence of the conductance on different geometric variables has further been investigated systematically by performing constrained geometry optimizations along a number of angle and dihedral coordinates. The largest changes in the conductance are observed when the Au-S-C angle and the Au-S-C-C dihedral are simultaneously constrained.
First‐row transition metal oxides are promising materials for catalyzing the oxygen evolution reaction. Surface sensitive techniques provide a unique perspective allowing the study of the structure, adsorption sites, and reactivity of catalysts at the atomic scale, which furnishes rationalization and improves the design of highly efficient catalytic materials. Here, a scanning probe microscopy study complemented by density functional theory on the structural and electronic properties of CoO nanoislands grown on Au(111) is reported. Two distinct phases are observed: The most extended displays a Moiré pattern (α‐region), while the less abundant is 1Co:1Au coincidental (β‐region). As a result of the surface registry, in the β‐region the oxide adlayer is compressed by 9%, increasing the unoccupied local density of states and enhancing the selective water adsorption at low temperature through a cobalt inversion mechanism. Tip‐induced voltage pulses irreversibly transform α‐ into β‐regions, thus opening avenues to modify the structure and reactivity of transition metal oxides by external stimuli like electric fields.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.