Clean and reproducible voltammetry of copper single crystals with prominent facet-specific features using induction annealing

Although copper is widely used as an electrocatalyst for the CO2 reduction reaction, often little emphasis is placed on identifying exactly the facet distribution of the copper surface. Furthermore, because of differing surface preparation methodologies, reported characaterization voltammograms (where applicable) often vary significantly between laboratories, even for surfaces of supposedly the same orientation. In this work, we describe a surface preparation methodology involving the combination of induction annealing and well-documented electrochemical steps, by which reproducible voltammetry for copper surfaces of different orientations can be obtained. Specifically, we investigated copper surfaces of the three principal orientations: {111}, {100} and {110}, and a representative polycrystalline surface. We compared these surfaces to surfaces reported in the literature prepared via either electropolishing or UHV-standard methodologies, where we find induction preparation to yield improvements in surface quality with respect to electropolished surfaces, though not quite as good as those obtained by UHV-preparation.Catalysis and Surface Chemistr

Reprint of "Electrocatalytic CO2 reduction to C2+ products on Cu and CuxZny electrodes: effects of chemical composition and surface morphology"

refers to​​​​​​​Alisson H.M. da Silva, Stefan J. Raaijman, Cássia S. Santana, José M. Assaf, Janaina F. Gomes, Marc T.M. KoperElectrocatalytic CO2 reduction to C2+ products on Cu and CuxZny electrodes: Effects of chemical composition and surface morphologyJournal of Electroanalytical Chemistry, Volume 880, 1 January 2021, Pages 114750The electrocatalytic CO2 reduction reaction (CO2RR) is a promising strategy for producing multi carbon compounds using only CO2 and H2O at room temperature. Significant advances have already been achieved in understanding how some characteristics of copper electrodes, the current state-of-the-art catalyst for multi carbon formation via CO2RR, affect the product spectrum. Advances and insights have been reported for, among others, the effect of crystallographic orientation, active surface area, and composition of M copper (M = Au, Ag, Zn, etc.) materials, and how these alter the distribution of CO2RR products. However, a systematic study evaluating the significance of these variables in the CO2RR to C2+ products is still lacking in the literature and represents an important step in the development of new materials with optimized properties that can be more selective to C2+ compounds. In this paper, we have systematically investigated the effect of the roughness factor, chemical composition, and surface morphology of CuxZny electrocatalysts on the product distribution during CO2RR. Firstly, Cu, Cu90Zn10, and Cu75Zn25 electrodes were exposed to oxidation-reduction cycles to produce Cu and CuxZny electrodes with different morphologies, roughness factors, and chemical composition. Our results show that an increase in the roughness factor and Zn content lead to higher faradaic efficiency (FE) to C2+ products. Furthermore, the influence of the nanoscale morphology is imperative for the production of C2+ compounds. Specifically, nanocubes of Cu and CuxZny presented the highest FE to C2+ products among the different surface morphologies studied in this work (polished flat surface, nanosheres, nanocubes, nanodendrites, and nanocauliflowers), showing that C-C coupling during CO2RR is mainly shape dependent.Catalysis and Surface Chemistr

Electrocatalytic CO2 reduction to C2+ products on Cu and CuxZny electrodes: effects of chemical composition and surface morphology

The electrocatalytic CO2 reduction reaction (CO2RR) is a promising strategy for producing multi-carbon compounds using only CO2 and H2O at room temperature. Significant advances have already been achieved in understanding how some characteristics of copper electrodes, the current state-of-the-art catalyst for multi-carbon formation via CO2RR, affect the product spectrum. Advances and insights have been reported for, among others, the effect of crystallographic orientation, active surface area, and composition of M-copper (M = Au, Ag, Zn, etc.) materials, and how these alter the distribution of CO2RR products. However, a systematic study evaluating the significance of these variables in the CO2RR to C2+ products is still lacking in the literature and represents an important step in the development of new materials with optimized properties that can be more selective to C2+ compounds. In this paper, we have systematically investigated the effect of the roughness factor, chemical composition, and surface morphology of CuxZny electrocatalysts on the product distribution during CO2RR. Firstly, Cu, Cu90Zn10, and Cu75Zn25 electrodes were exposed to oxidation-reduction cycles to produce Cu and CuxZny electrodes with different morphologies, roughness factors, and chemical composition. Our results show that an increase in the roughness factor and Zn content lead to higher faradaic efficiency (FE) to C2+ products. Furthermore, the influence of the nanoscale morphology is imperative for the production of C2+ compounds. Specifically, nanocubes of Cu and CuxZny presented the highest FE to C2+ products among the different surface morphologies studied in this work (polished flat surface, nanosheres, nanocubes, nanodendrites, and nanocauliflowers), showing that CC coupling during CO2RR is mainly shape dependent.Catalysis and Surface Chemistr

Possible symmetries of the superconducting order parameter in a hexagonal ferromagnet

We study the order parameter symmetry in a hexagonal crystal with co-existing superconductivity and ferromagnetism. An experimental example is provided by carbon-based materials, such as graphite-sulfur composites, in which an evidence of such co-existence has been recently discovered. The presence of a non-zero magnetization in the normal phase brings about considerable changes in the symmetry classification of superconducting states, compared to the non-magnetic case.Comment: 4 pages, REVTe

Kullback-Leibler and Renormalized Entropy: Applications to EEGs of Epilepsy Patients

Recently, renormalized entropy was proposed as a novel measure of relative entropy (P. Saparin et al., Chaos, Solitons & Fractals 4, 1907 (1994)) and applied to several physiological time sequences, including EEGs of patients with epilepsy. We show here that this measure is just a modified Kullback-Leibler (K-L) relative entropy, and it gives similar numerical results to the standard K-L entropy. The latter better distinguishes frequency contents of e.g. seizure and background EEGs than renormalized entropy. We thus propose that renormalized entropy might not be as useful as claimed by its proponents. In passing we also make some critical remarks about the implementation of these methods.Comment: 15 pages, 4 Postscript figures. Submitted to Phys. Rev. E, 199

Decomposition and nutrient release of leguminous plants in coffee agroforestry systems.

Leguminous plants used as green manure are an important nutrient source for coffee plantations, especially for soils with low nutrient levels. Field experiments were conducted in the Zona da Mata of Minas Gerais State, Brazil to evaluate the decomposition and nutrient release rates of four leguminous species used as green manures (Arachis pintoi, Calopogonium mucunoides, Stizolobium aterrimum and Stylosanthes guianensis) in a coffee agroforestry system under two different climate conditions. The initial N contents in plant residues varied from 25.7 to 37.0 g kg-1 and P from 2.4 to 3.0 g kg-1. The lignin/N, lignin/polyphenol and(lignin+polyphenol)/N ratios were low in all residues studied. Mass loss rates were highest in the first 15 days, when 25 % of the residues were decomposed. From 15 to 30 days, the decomposition rate decreased on both farms. On the farm in Pedra Dourada (PD), the decomposition constant k increased in the order C. mucunoides < S. aterrimum < S. guianensis < A. pintoi. On the farm in Araponga (ARA), there was no difference in the decomposition rate among leguminous plants. The N release rates varied from 0.0036 to 0.0096 d-1. Around 32 % of the total N content in the plant material was released in the first 15 days. In ARA, the N concentration in the S. aterrimum residues was always significantly higher than in the other residues. At the end of 360 days, the N released was 78 % in ARA and 89 % in PD of the initial content. Phosphorus was the most rapidly released nutrient (k values from 0.0165 to 0.0394 d-1). Residue decomposition and nutrient release did not correlate with initial residue chemistry and biochemistry, but differences in climatic conditions between the two study sites modified the decomposition rate constants

Stellar evolution and modelling stars

In this chapter I give an overall description of the structure and evolution of stars of different masses, and review the main ingredients included in state-of-the-art calculations aiming at reproducing observational features. I give particular emphasis to processes where large uncertainties still exist as they have strong impact on stellar properties derived from large compilations of tracks and isochrones, and are therefore of fundamental importance in many fields of astrophysics.Comment: Lecture presented at the IVth Azores International Advanced School in Space Sciences on "Asteroseismology and Exoplanets: Listening to the Stars and Searching for New Worlds" (arXiv:1709.00645), which took place in Horta, Azores Islands, Portugal in July 201

Exchange, use and conservation of animal genetic resources : policy and regulatory options

The aim of this report is to support informed and evidence-based decision-making by exploring a range of policy and regulatory options related to exchange, use and conservation of AnG