Your search keyword '"Alina I. Belova"' showing total 7 results

1. Mechanism of Oxygen Reduction in Aprotic Li–Air Batteries: The Role of Carbon Electrode Surface Structure

Author

David G. Kwabi, Lada V. Yashina, Alina I. Belova, Yang Shao-Horn, and Daniil M. Itkis

Subjects

Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, Glassy carbon, 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Oxygen, 0104 chemical sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, General Energy, chemistry, Highly oriented pyrolytic graphite, Chemisorption, Pyrolytic carbon, Physical and Theoretical Chemistry, Cyclic voltammetry, 0210 nano-technology, Carbon

Abstract

Electrochemical oxygen reduction in aprotic media is a key process that determines the operation of advanced metal–oxygen power sources, e.g., Li–O2 batteries. In such systems oxygen reduction on carbon-based positive electrodes proceeds through a complicated mechanism that comprises several chemical and electrochemical steps involving either dissolved or adsorbed species, and as well side reactions with carbon itself. Here, cyclic voltammetry was used to reveal the effects of imperfections in the planar sp2 surface structure of carbon on the Li oxygen reduction reaction (Li-ORR) mechanism by means of different model carbon electrodes (highly oriented pyrolytic graphite (HOPG), glassy carbon, basal, and edge planes of pyrolytic graphite), in dimethyl sulfoxide (DMSO)-based electrolyte. We show that the first electron transfer step O2 + e– ⇆ O2– (followed by ion-coupling Li+ + O2– ⇆ LiO2) does not involve oxygen chemisorption on carbon as evidenced by the independence of its rate on the carbon electrode su...

Published

2017

2. Notable reactivity of acetonitrile towards Li2O2/LiO2 probed by NAP XPS during Li–O2 battery discharge

Author

Juan-Jesús Velasco-Vélez, Alexander S. Frolov, Lada V. Yashina, Denis V. Vyalikh, Daniil M. Itkis, Axel Knop-Gericke, Tatiana K. Zakharchenko, Olesya O. Kapitanova, Alina I. Belova, Ministry of Education and Science of the Russian Federation, German-Russian Interdisciplinary Science Center, Federal Ministry of Education and Research (Germany), and Helmholtz-Zentrum Berlin for Materials and Energy

Subjects

Battery (electricity), Passivation, Inorganic chemistry, 02 engineering and technology, General Chemistry, Electrolyte, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, 0104 chemical sciences, Electrochemical cell, chemistry.chemical_compound, chemistry, X-ray photoelectron spectroscopy, Reactivity (chemistry), 0210 nano-technology, Acetonitrile, Faraday efficiency

Abstract

One of the key factors responsible for the poor cycleability of Li–O2 batteries is a formation of byproducts from irreversible reactions between electrolyte and discharge product Li2O2 and/or intermediate LiO2. Among many solvents that are used as electrolyte component for Li–O2 batteries, acetonitrile (MeCN) is believed to be relatively stable towards oxidation. Using near ambient pressure X-ray photoemission spectroscopy (NAP XPS), we characterized the reactivity of MeCN in the Li–O2 battery. For this purpose, we designed the model electrochemical cell assembled with solid electrolyte. We discharged it first in O2 and then exposed to MeCN vapor. Further, the discharge was carried out in O2 + MeCN mixture. We have demonstrated that being in contact with Li–O2 discharge products, MeCN oxidizes. This yields species that are weakly bonded to the surface and can be easily desorbed. That’s why they cannot be detected by the conventional XPS. Our results suggest that the respective chemical process most probably does not give rise to electrode passivation but can decrease considerably the Coulombic efficiency of the battery., This work of A.K-G., J.J.V-V. and D.M.I. was supported by the Russian Ministry of Science and Education (RFMEFI61614×0007) and Bundesministerium für Bildung and Forschung (Project No. 05K2014) in the framework of the joint Russian-German research project “SYnchrotron and NEutron STudies for Energy Storage (SYNESTESia)”. T.K.Z acknowledges Center for Electrochemical Energy of Skolkovo Institute of Science and Technology for financial support. The work of O.O.K., A.I.B and L.V.Y. is performed within the joint project of the Russian Science Foundation (16-42-01093) and DFG (LA655-17/1). We are grateful to HZB for beamtime granted at ISISS and RGBL beamlines. T.K.Z. and A.S.F. thank to the Russian German laboratory at HZB for support provided. Authors are appreciated to Victor Vizgalov for solid electrolyte membrane preparation. Travelling of T.K.Z. was supported by German-Russian Interdisciplinary Science Center (G-RISC).

Published

2018

3. Can surface reactivity of mixed crystals be predicted from their counterparts? A case study of <tex>(Bi_{1-x}Sb_{x})_{2}Te_{3}$</tex> topological insulators

Author

Maria Batuk, Andrey A. Volykhov, Virginia Pérez-Dieste, Vera S. Neudachina, Carolien Callaert, Carlos Escudero, Nikolay O. Khmelevsky, Axel Knop-Gericke, M. E. Tamm, Anna P. Sirotina, Joke Hadermann, Lada V. Yashina, Nadezhda V. Vladimirova, Alina I. Belova, and Jaime Sánchez-Barriga

Subjects

Materials science, Physics, Fermi level, Oxide, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Amorphous solid, Crystal, chemistry.chemical_compound, symbols.namesake, chemistry, Chemical physics, Ternary compound, Topological insulator, 0103 physical sciences, Atom, Materials Chemistry, symbols, 010306 general physics, 0210 nano-technology, Surface states

Abstract

The behavior of ternary mixed crystals or solid solutions and its correlation with the properties of their binary constituents is of fundamental interest. Due to their unique potential for application in future information technology, mixed crystals of topological insulators with the spin-locked, gapless states on their surfaces attract huge attention of physicists, chemists and material scientists. (Bi1−xSbx)2Te3 solid solutions are among the best candidates for spintronic applications since the bulk carrier concentration can be tuned by varying x to obtain truly bulk-insulating samples, where the topological surface states largely contribute to the transport and the realization of the surface quantum Hall effect. As this ternary compound will be evidently used in the form of thin-film devices its chemical stability is an important practical issue. Based on the atomic resolution HAADF-TEM and EDX data together with the XPS results obtained both ex situ and in situ, we propose an atomistic picture of the mixed crystal reactivity compared to that of its binary constituents. We find that the surface reactivity is determined by the probability of oxygen attack on the Te–Sb bonds, which is directly proportional to the number of Te atoms bonded to at least one Sb atom. The oxidation mechanism includes formation of an amorphous antimony oxide at the very surface due to Sb diffusion from the first two quintuple layers, electron tunneling from the Fermi level of the crystal to oxygen, oxygen ion diffusion to the crystal, and finally, slow Te oxidation to the +4 oxidation state. The oxide layer thickness is limited by the electron transport, and the overall process resembles the Cabrera–Mott mechanism in metals. These observations are critical not only for current understanding of the chemical reactivity of complex crystals, but also to improve the performance of future spintronic devices based on topological materials.

Published

2018

4. Laterally selective oxidation of large-scale graphene with atomic oxygen

Author

M. Al-Hada, Tae Won Kang, Dmitry Yu. Usachov, Denis V. Vyalikh, Olesya O. Kapitanova, Daniil M. Itkis, Luca Gregoratti, Alexei Barinov, Anna P. Sirotina, Matteo Amati, Hak Dong Cho, Lada V. Yashina, Elmar Yu. Kataev, Gennady N. Panin, Hikmet Sezen, Alina I. Belova, German Research Foundation, Russian Foundation for Basic Research, and Russian Science Foundation

Subjects

Auger electron spectroscopy, Materials science, Graphene, Bilayer, Analytical chemistry, 02 engineering and technology, 021001 nanoscience & nanotechnology, 01 natural sciences, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, law.invention, symbols.namesake, General Energy, X-ray photoelectron spectroscopy, law, 0103 physical sciences, Microscopy, symbols, Physical and Theoretical Chemistry, 010306 general physics, 0210 nano-technology, Raman spectroscopy, Layer (electronics), FOIL method

Abstract

Using X-ray photoemission microscopy, we discovered that oxidation of commercial large-scale graphene on Cu foil, which typically has bilayer islands, by atomic oxygen proceeds with the formation of the specific structures: though relatively mobile epoxy groups are generated uniformly across the surface of single-layer graphene, their concentration is significantly lower for bilayer islands. More oxidized species like carbonyl and lactones are preferably located at the centers of these bilayer islands. Such structures are randomly distributed over the surface with a mean density of about 3× 106 cm–2 in our case. Using a set of advanced spectromicroscopy instruments including Raman microscopy, X-ray photoelectron spectroscopy (μ-XPS), Auger electron spectroscopy (nano-AES), and angle-resolved photoelectron spectroscopy (μ-ARPES), we found that the centers of the bilayer islands where the second layer nucleates have a high defect concentration and serve as the active sites for deep oxidation. This information can be potentially useful in developing lateral heterostructures for electronics and optoelectronics based on graphene/graphene oxide heterojunctions., The work is performed within the joint project of the Russian Science Foundation (16-42-01093) and DFG (LA655-17/1). The work of O.O.K. was supported by the Russian Foundation of Basic Researches (individual project 16-33-60229).

Published

2017

5. Reactivity of Carbon in Lithium–Oxygen Battery Positive Electrodes

Author

Eugene A. Goodilin, Anna P. Sirotina, Elmar Yu. Kataev, Daniil M. Itkis, Lada V. Yashina, Michael Hävecker, Alexei Barinov, Dmitry A. Semenenko, Yang Shao-Horn, Alina I. Belova, Vera S. Neudachina, Pavel Dudin, Detre Teschner, and Axel Knop-Gericke

Subjects

chemistry.chemical_classification, Battery (electricity), Double bond, Chemistry, Mechanical Engineering, Inorganic chemistry, chemistry.chemical_element, Bioengineering, General Chemistry, Condensed Matter Physics, Oxygen, Cathode, law.invention, law, General Materials Science, Reactivity (chemistry), Lithium, Carbon, Lithium–air battery

Abstract

Unfortunately, the practical applications of Li-O2 batteries are impeded by poor rechargeability. Here, for the first time we show that superoxide radicals generated at the cathode during discharge react with carbon that contains activated double bonds or aromatics to form epoxy groups and carbonates, which limits the rechargeability of Li-O2 cells. Carbon materials with a low amount of functional groups and defects demonstrate better stability thus keeping the carbon will-o'-the-wisp lit for lithium-air batteries.

Published

2013

6. Tuning surface chemistry of TiC electrodes for lithium–air batteries

Author

Daniil M. Itkis, Matteo Amati, Boris Senkovsky, Lada V. Yashina, Yang Shao-Horn, Anna Ya. Kozmenkova, Denis V. Vyalikh, Luca Gregoratti, Elmar Yu. Kataev, Axel Knop-Gericke, Alina I. Belova, Juan J. Velasco-Vélez, Ministry of Education and Science of the Russian Federation, Federal Ministry of Education and Research (Germany), and German-Russian Interdisciplinary Science Center

Subjects

Battery (electricity), Materials science, Titanium carbide, General Chemical Engineering, Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, General Chemistry, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Oxygen, Cathode, 0104 chemical sciences, law.invention, chemistry.chemical_compound, chemistry, law, Materials Chemistry, Lithium, Surface layer, 0210 nano-technology, Carbon, Lithium peroxide

Abstract

One of the key problems hindering practical implementation of lithium–air batteries is caused by carbon cathode chemical instability leading to low energy efficiency and short cycle life. Titanium carbide (TiC) nanopowders are considered as an alternative cathode material; however, they are intrinsically reactive toward oxygen, and its stability is controlled totally by a surface overlayers. Using photoemission spectroscopy, we show that lithium–air battery discharge product, lithium peroxide (Li2O2), easily oxidizes clean TiC surface. At the same time, TiC surface, which was treated by molecular oxygen under ambient conditions, shows much better stability in contact with Li2O2 that can be explained by the presence of a surface layer containing a significant amount of elemental carbon in addition to oxides and oxycarbides. Nevertheless, such protective coatings produced by room temperature oxidation are not practically useful as one of its components, elemental carbon, is oxidized in the presence of lithium–air battery discharge intermediates. These results are of critical importance in understanding of TiC surface chemistry and in design of stable lithium–air battery electrodes. We postulate that dense, uniform, carbon-free titanium dioxide surface layers of 2–3 nm thickness on TiC will be a promising solution, and thus further efforts should be taken for developing synthetic protocols enabling preparation of TiO2/TiC core–shell structures., This work was financially supported by the Russian Ministry of Science and Education (RFMEFI61614X0007) and Bundesministerium für Bildung and Forschung (project no. 05K2014) in the framework of the joint Russian-German research project “SYnchrotron and NEutron STudies for Energy Storage (SYNESTESia)”.

Published

2016

7. Protected anodes for lithium-air batteries

Author

Gleb Yu. Aleshin, Yurii D. Tretyakov, Dmitry A. Semenenko, Alina I. Belova, Eugene A. Goodilin, Daniil M. Itkis, and Tatyana K. Zakharchenko

Subjects

Battery (electricity), Materials science, Lithium vanadium phosphate battery, Inorganic chemistry, chemistry.chemical_element, General Chemistry, Electrolyte, Condensed Matter Physics, Cathode, Anode, law.invention, Chemical engineering, chemistry, law, medicine, General Materials Science, Lithium, Lithium–air battery, Activated carbon, medicine.drug

Abstract

A new protected anode for lithium-air batteries is designed using lithium foil and lithium–aluminium–germanium–phosphorus glass–ceramics (LAGP) with improved specific conductivity exceeding 3.1 ⋅ 10− 4 S cm− 1 at 80 °C and 1.4 ⋅ 10− 4 S cm− 1 at − 20 °C. Prevention of anode or electrolyte degradation provided stability of the battery characteristics for at least 10 cycles. In particular, a lithium-air battery with the protected anode and an activated carbon cathode modified with α-MnO2 nanorod catalyst showed a specific capacity of about 3000 mAh g− 1.

Published

2011