electronic configuration
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Author(s):  
HAI LIN ◽  
Dariusz Jakub Gawryluk ◽  
Yannick Maximilian Klein ◽  
Shangxiong Huangfu ◽  
Ekaterina Pomjakushina ◽  
...  

Abstract Motivated by the recent discovery of superconductivity in infinite-layer nickelate thin films, we report on a synthesis and magnetization study on bulk samples of the parent compounds RNiO2 (R=La, Pr, Nd). The frequency-dependent peaks of the AC magnetic susceptibility, along with remarkable memory effects, characterize spin-glass states. Furthermore, various phenomenological parameters via different spin glass models show strong similarity within these three compounds as well as with other rare-earth metal nickelates. The universal spin-glass behaviour distinguishes the nickelates from the parent compound CaCuO2 of cuprate superconductors, which has the same crystal structure and d9 electronic configuration but undergoes a long-range antiferromagnetic order. Our investigations may indicate a distinctly different nature of magnetism and superconductivity in the bulk nickelates than in the cuprates.


2021 ◽  
Vol 11 (40) ◽  
pp. 192-193
Author(s):  
Cloe Taddei-Ferretti

Background and Aims. There are several experimental evidences for the effects of high-diluted substances (see e.g. C. Taddei-Ferretti, A. Cotugno 1997, on effects of high-diluted drugs on the prevention and control of mice teratogenicity induced by purine derivatives; N.C. Sukul, C. Taddei-Ferretti, S.P. Sinha Babu, A. De, B. Nandi, A. Sukul, R. Dutta-Nag 2000, on high-diluted Nux vomica countering alcohol-induced loss of righting reflex in toads). Also the physical characterization and mechanism of action of high-diluted drugs have been studied (see e.g. N.C. Sukul, A. Sukul, High dilution effects: Physical and biochemical basis 2004). However, further experimental researches are needed to clarify how physical characteristics of a drug are linked to its global biological effects. Considerations on some high-diluted mineral remedies will be developer here. Methods. In Organon, sect. 119, S. Hahnemann writes: «As certainly each species of plants is different from every other one with regard to external appearance, way of life and growth, taste and smell, and as certainly each mineral, each salt is different from the others with regard to external, internal, physical and chemical qualities [...], so certainly all these vegetal and mineral substances have pathogenetic – and thus also curative – effects different among themselves [...]». This statement may be taken as basis for considering the characteristics of some elements, as ordered in the periodic table, in relation to those of some high-diluted mineral remedies. Conclusions. The elements were previously ordered in the periodic table according to the atomic weight chemically determined, and later more precisely according to the atomic number (number of protons). Then also the electronic configuration was taken into account: properties depending on atomic mass and deep electrons are not periodical, while chemical and several physical properties are linked to external electrons which have periodical configuration. In particular, let us consider the group of elements C, P, S, Cl and the group of elements Ca, Mg, K, Na. One may conclude that the four elements of the first group (respectively receiver-or-donor of 4 electrons, receiver of 3, of 2, of 1 electron), which, according to H. Bernard, are linked to the fixed human constitutions, are close among themselves in the periodic table, while they are very distant from the four elements of the second group (respectively donor of 2, of 2, of 1, of 1 electron), which are close among themselves and are linked to the changing constitutional stages.


2021 ◽  
Vol 2021 ◽  
pp. 1-7
Author(s):  
T. Usami ◽  
S. A. Salman ◽  
K. Kuroda ◽  
M. K. Gouda ◽  
A. Mahdy ◽  
...  

Cobalt-nickel nanoparticles (Co-Ni-NPs) show promising electrochemical performance in oxygen and hydrogen evolution reactions (OER and HER) due to their physicochemical properties such as electronic configuration and great electrochemical stability. Therefore, developing new economically and environmentally friendly methods of synthesizing Co-Ni-NPs has become a practical requirement. Co-Ni-NPs were produced by employing the liquid-phase reduction method. Nickel and cobalt sulfate solutions in hydrazine monohydrate with various mixing ratios were used as raw materials. Nickel plays an important role in the nucleation process via increasing the reduction reaction rate throughout the formation of Co-Ni-NPs. Furthermore, the acceleration of the Co-Ni-NPs formation process may be attributed to the partial dissolution of Ni(OH)2 in the presence of N2H4 and/or citrate-anions and the formation of the Ni-N2H4 or Ni-Cit complexes in contrast to Co(OH)2.


Catalysts ◽  
2021 ◽  
Vol 11 (12) ◽  
pp. 1520
Author(s):  
Elisa Gaggero ◽  
Paola Calza ◽  
Erik Cerrato ◽  
Maria Cristina Paganini

In the last decades photocatalysis has become one of the most employed technologies for the implementation of the so-called Advanced Oxidation Processes (AOPs) for the removal of harmful pollutants from wastewaters. The materials identified as the best photocatalysts are transition metal oxides, in which the band structure allows charge carrier separation upon solar irradiation. The photoinduced charge carrier can thus cause oxidative and reductive redox reactions at the surface, inducing the formation of the radical species able to initiate the AOPs. Despite the great advantages of this process (non-toxic, cheap and environmentally clean), the main drawback lies in the fact that the most efficient semiconductors are only able to absorb UV irradiation, which accounts for only 5% of the total solar irradiation at the Earth’s surface and not enough to generate the required amount of electron-hole pairs. On the other hand, many efforts have been devoted to the sensitization of wide band gap transition metal oxides to visible light, which represents a higher percentage (almost 45%) in the solar electromagnetic spectrum. Among all the strategies to sensitize transition metal oxides to visible irradiation, doping with lanthanides has been less explored. In this regard, lanthanides offer a unique electronic configuration, consisting in 4f orbitals shielded by a 5s5p external shell. This occurrence, coupled with the different occupation of the localized 4f orbitals would provide an astounding opportunity to tune these materials’ properties. In this review we will focus in depth on the modification of two promising photocatalytic transition metal oxides, namely ZnO and ZrO2, with cerium, europium and erbium atoms. The aim of the work is to provide a comprehensive overview of the influence of lanthanides on the structural, optical and electronic properties of the modified materials, emphasizing the effect of the different 4f orbital occupation in the three considered doping atoms. Moreover, a large portion of the discussion will be devoted to the structural-properties relationships evidencing the improved light absorption working mechanism of each system and the resulting enhanced photocatalytic performance in the abatement of contaminants in aqueous environments.


2021 ◽  
Author(s):  
Bareld Wit ◽  
Radovan Vranik ◽  
Stefan Müllegger

Abstract Diverse spectroscopic methods operating at radio frequency depend on a reliable calibration to compensate for the frequency dependent damping of the transmission lines. Calibration may be impeded by the existence of a sensitive interdependence of two or more experimental parameters. Here, we show by combined scanning tunnelling microscopy measurements and numerical simulations how a frequency-dependent conductance response is affected by different DC conductance behaviour of the sample. Distinct and well-defined DC-conductance behaviour is provided by our experimental model systems, which include C60 molecules on Au(111), exhibiting electronic configurations distinct from the well-known dim and bright C60’s reported so far. We investigate specific combinations of sample electronic configuration, DC bias voltage, and radio frequency modulation amplitude. Variations of the modulation amplitude as small as only a few percent may result in systematic conductance deviations as large as one order of magnitude. We provide practical guidelines for calibrating respective measurements, which are relevant to RF spectroscopic measurements.


2021 ◽  
Vol 26 (6) ◽  
pp. 580-583
Author(s):  
S.A. Neoustroev ◽  

Energy spectrum of gas particles in plasma is broad, ranging from fractions to 10s of electron volts. Proportion of particles with required energetic parameters, participating in cubic carbon c-C synthesis, is small. External energy deposition can transfer an inert carbon atom to active state and change its electronic configuration. Binding energy of c-C atom depends on energy sources interaction. In this work, the calculations found the binding energy value that was compared with value of energy of the bond between the carbon atoms in ethane. The advisability of external source, activated carbon atoms generator, is marked. It has been established that by adding accelerated carbon atoms with energy of 9,687 eV into reactor it is possible to increase productivity of films, coatings and bulk crystals growth.


2021 ◽  
Vol 8 ◽  
Author(s):  
Nieves López-Salas ◽  
Josep Albero

The search for metal-free and visible light-responsive materials for photocatalytic applications has attracted the interest of not only academics but also the industry in the last decades. Since graphitic carbon nitride (g-C3N4) was first reported as a metal-free photocatalyst, this has been widely investigated in different light-driven reactions. However, the high recombination rate, low electrical conductivity, and lack of photoresponse in most of the visible range have elicited the search for alternatives. In this regard, a broad family of carbon nitride (CxNy) materials was anticipated several decades ago. However, the attention of the researchers in these materials has just been awakened in the last years due to the recent success in the syntheses of some of these materials (i.e., C3N3, C2N, C3N, and C3N5, among others), together with theoretical simulations pointing at the excellent physico-chemical properties (i.e., crystalline structure and chemical morphology, electronic configuration and semiconducting nature, or high refractive index and hardness, among others) and optoelectronic applications of these materials. The performance of CxNy, beyond C3N4, has been barely evaluated in real applications, including energy conversion, storage, and adsorption technologies, and further work must be carried out, especially experimentally, in order to confirm the high expectations raised by simulations and theoretical calculations. Herein, we have summarized the scarce literature related to recent results reporting the synthetic routes, structures, and performance of these materials as photocatalysts. Moreover, the challenges and perspectives at the forefront of this field using CxNy materials are disclosed. We aim to stimulate the research of this new generation of CxNy-based photocatalysts, beyond C3N4, with improved photocatalytic efficiencies by harnessing the striking structural, electronic, and optical properties of this new family of materials.


Author(s):  
Shivaraju Guddehalli Chandrappa ◽  
Prabu Moni ◽  
Dehong Chen ◽  
Guruprakash Karkera ◽  
Kunkanadu R. Prakasha ◽  
...  

Molecules ◽  
2021 ◽  
Vol 26 (22) ◽  
pp. 6924
Author(s):  
Andrés Robles-Navarro ◽  
Carlos Cárdenas ◽  
Patricio Fuentealba

The electronegativity concept was first formulated by Pauling in the first half of the 20th century to explain quantitatively the properties of chemical bonds between different types of atoms. Today, it is widely known that, in high-pressure regimes, the reactivity properties of atoms can change, and, thus, the bond patterns in molecules and solids are affected. In this work, we studied the effects of high pressure modeled by a confining potential on different definitions of electronegativity and, additionally, tested the accuracy of first-order perturbation theory in the context of density functional theory for confined atoms of the second row at the Hartree–Fock level. As expected, the electronegativity of atoms at high confinement is very different than that of their free counterparts since it depends on the electronic configuration of the atom, and, thus, its periodicity is modified at higher pressures.


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