Your search keyword '"Stoyanova, Radostina"' showing total 13 results

1. Review and New Perspectives on Non-Layered Manganese Compounds as Electrode Material for Sodium-Ion Batteries.

Author

Alcántara, Ricardo, Pérez-Vicente, Carlos, Lavela, Pedro, Tirado, José L., Medina, Alejandro, and Stoyanova, Radostina

Subjects

MANGANESE compounds, SODIUM ions, TRANSITION metals, PRUSSIAN blue, ELECTRODES, ELECTRIC batteries, COBALT compounds, TRANSITION metal oxides

Abstract

After more than 30 years of delay compared to lithium-ion batteries, sodium analogs are now emerging in the market. This is a result of the concerns regarding sustainability and production costs of the former, as well as issues related to safety and toxicity. Electrode materials for the new sodium-ion batteries may contain available and sustainable elements such as sodium itself, as well as iron or manganese, while eliminating the common cobalt cathode compounds and copper anode current collectors for lithium-ion batteries. The multiple oxidation states, abundance, and availability of manganese favor its use, as it was shown early on for primary batteries. Regarding structural considerations, an extraordinarily successful group of cathode materials are layered oxides of sodium, and transition metals, with manganese being the major component. However, other technologies point towards Prussian blue analogs, NASICON-related phosphates, and fluorophosphates. The role of manganese in these structural families and other oxide or halide compounds has until now not been fully explored. In this direction, the present review paper deals with the different Mn-containing solids with a non-layered structure already evaluated. The study aims to systematize the current knowledge on this topic and highlight new possibilities for further study, such as the concept of entatic state applied to electrodes. [ABSTRACT FROM AUTHOR]

Published

2023

2. Carbon-Based Composites with Mixed Phosphate-Pyrophosphates with Improved Electrochemical Performance at Elevated Temperature.

Author

Harizanova, Sonya, Tushev, Trajche, Koleva, Violeta, and Stoyanova, Radostina

Subjects

HIGH temperatures, LITHIUM cells, LITHIUM-ion batteries, CARBON-black, GRAPHENE oxide, PYROPHOSPHATES

Abstract

Sodium iron phosphate-pyrophosphate, Na4Fe3(PO4)2P2O7 (NFPP) emerges as an excellent cathode material for sodium-ion batteries. Because of lower electronic conductivity, its electrochemical performance depends drastically on the synthesis method. Herein, we provide a simple and unified method for synthesis of composites between NFPP and reduced graphene oxide (rGO) and standard carbon black, designed as electrode materials for both sodium- and lithium-ion batteries. The carbon additives affect only the morphology and textural properties of the composites. The performance of composites in sodium and lithium cells is evaluated at elevated temperatures. It is found that NFPP/rGO outperforms NFPP/C in both Na and Li storage due to its hybrid mechanism of energy storage. In sodium half-cells, NFPP/rGO delivers a reversible capacity of 95 mAh/g at 20 °C and 115 mAh/g at 40 °C with a cycling stability of 95% and 88% at a rate of C/2. In lithium half-cells, the capacity reaches a value of 120 mAh/g at 20 and 40 °C, but the cycling stability becomes worse, especially at 40 °C. The electrochemical performance is discussed on the basis of ex situ XRD and microscopic studies. The good Na storage performance of NFPP/rGO at an elevated temperature represents a first step towards its commercialization. [ABSTRACT FROM AUTHOR]

Published

2023

3. High-Performance Full Sodium Cells Based on MgO-Treated P2-Type Na 0.67 (Mn 0.5 Fe 0.5) 1−x Co x O 2 Cathodes.

Author

Taskiran, Nermin, Altundag, Sebahat, Koleva, Violeta, Altin, Emine, Arshad, Muhammad, Avci, Sevda, Ates, Mehmet Nurullah, Altin, Serdar, and Stoyanova, Radostina

Subjects

TRANSITION metal oxides, TRANSITION metal ions, SURFACE area measurement, SODIUM ions, CATHODES, CHEMICAL formulas, SODIUM

Abstract

Herein, we design a cathode material based on layered Na2/3(Mn1/2Fe1/2)O2 for practical application by combining the Co substitution and MgO treatment strategies. The oxides are prepared via solid-state reactions at 900 °C. The structure, morphology, and oxidation state of transition metal ions for Co-substituted and MgO-treated oxides are carefully examined via X-ray diffraction, IR and Raman spectroscopies, FESEM with EDX, specific surface area measurement, and XPS spectroscopy. The ability of oxides to store sodium reversibly is analyzed within a temperature range of 10 to 50 °C via CV experiments, galvanostatic measurements, and EIS, using half and full sodium ion cells. The changes in the local structure and oxidation state of transition metal ions during Na+ intercalation are monitored via operando XAS experiments. It is found that the Co substituents have a positive impact on the rate capability of layered oxides, while Mg additives lead to a strong increase in the capacity and an enhancement of the cycling stability. Thus, the highest capacity is obtained for 2 at.%-MgO-treated Na2/3(Mn1/2Fe1/2)0.9Co0.1O2 (175 mAh/g, with a capacity fade of 28% after 100 cycles). In comparison with Co substituents, the Mg treatment has a crucial role in the improvement of the lattice stability during the cycling process. The best electrode materials, with a chemical formula of 2 at.%-MgO treated Na2/3(Mn1/2Fe1/2)0.9Co0.1O2, were also used for the full cells design, with hard carbon as an anode. In the voltage window of 2–4 V, the capacity of the cells was obtained as 78 mAh/g and 51 mAh/g for applied current densities of 12 mA/g and 60 mA/g, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

4. Mixed Phosphate-Sulfate NASICON phase as Electrode Material in Sodium-Ion Batteries

Author

Koleva, Violeta, Stanchovska, Silva, Harizanova, Sonya, and Stoyanova, Radostina

Subjects

NASICON, Mixed phosphate-sulfate, Electrode materials, Sodium-ion batteries

Published

2022

5. Sodium titanate nanowires (Na2Ti3O7 and Na2Ti6O13) as anode materials in sodiumion batteries

Author

Stanchovska, Silva, Kalapsazova, Mariya, Harizanova, Sonya, Koleva, Violeta, and Stoyanova, Radostina

Subjects

anode materials, sodium-ion batteries, sodium titanates

Published

2022

6. Design of Sodium Titanate Nanowires as Anodes for Dual Li,Na Ion Batteries.

Author

Stanchovska, Silva, Kalapsazova, Mariya, Harizanova, Sonya, Koleva, Violeta, and Stoyanova, Radostina

Subjects

NANOWIRES, LITHIUM cells, CARBOXYMETHYLCELLULOSE, LITHIUM, ANODES, SODIUM

Abstract

The bottleneck in the implementation of hybrid lithium-sodium-ion batteries is the lack of anode materials with a desired rate capability. Herein, we provide an in-depth examination of the Li-storage performance of sodium titanate nanowires as negative electrodes in hybrid Li,Na-ion batteries. Titanate nanowires were prepared by a simple and reproducible hydrothermal method. At a low reaction pressure, the well-isolated nanowires are formed, while by increasing the reaction pressure from 2 to 30 bar, the isolated nanowires tend to bundle. In nanowires, the local coordinations of Na and Ti atoms deviate from those in Na2Ti3O7 and Na2Ti6O13 and slightly depend on the reaction pressure. During the annealing at 350 °C, both Na and Ti coordinations undergo further changes. The nanowires are highly defective, and they easily crystallize into Na2Ti6O13 and Na2Ti3O7 phases. The lithium storage properties are evaluated in lithium-ion cells vs. lithium metal anode and titanate electrodes fabricated with PVDF and carboxymethyl cellulose (CMC) binders. The Li-storage by nanowires proceeds by a hybrid capacitive-diffusive mechanism between 0.1 and 2.5 V, which enables to achieve a high specific capacity. Sodium titanates accommodate Li+ by formation of mixed lithium-sodium-phase Na2−xLixTi6O13, which is decomposed to the distinct lithium phases Li0.54Ti2.86O6 and Li0.5TiO2. Contrary to lithium, the sodium storage is accomplished mainly by the capacitive reactions, and thus the phase composition is preserved during cycling in sodium ion cells. The isolated nanowires outperform bundled nanowires with respect to rate capability. [ABSTRACT FROM AUTHOR]

Published

2023

7. Enhancing oxygen redox activity in sodium-deficient three-layered oxides: modeling the structure or the surface?

Author

Kalapsazova, Mariya, Kukeva, Rositsa, Zhecheva, Ekaterina, and Stoyanova, Radostina

Subjects

oxygen redox activity, sodium-ion batteries, layered oxides, surface modeling

Abstract

In this contribution we unveil the interplay between metal substitution, treatment with oxygen storage materials and anionic redox activity in sodium nickel manganese oxides with three-layer stacking (P3-Na2/3Ni1/2Mn1/2O2) during single Na+ and Li+ intercalation. As metal substituents, Mg2+ and Ti4+ ions were used through partial replacement of low- and high-oxidized nickel ions, respectively: Na2/3Ni1/3Mg1/6Mn1/2O2 and Na2/3Ni1/3Ti1/6Mn1/2O2. Furthermore, the metal-substituted oxides are treated with an oxygen storage material, such as CeO2. The effect of the metal substitution and CeO2-treatment on the structure and morphology of the oxides is observed by X-ray powder diffraction, EPR spectroscopy and HR-TEM. Cyclic voltammetry was employed to investigate the reduction and oxidation processes during Na+ and Li+ intercalation. The electrochemical tests are carried out in galvanostatic mode. The electrode–electrolyte interaction is monitored by ex-situ EPR of the long-cycled electrodes.

Published

2022

8. Aluminum doping and Al2O3 coating for improving the electrochemical performance of layered Na2/3Ni1/2Mn1/2O2

Author

Kalapsazova, Mariya, Zhecheva, Ekaterina, and Stoyanova, Radostina

Subjects

surface coating, sodium-ion batteries, structure modeling, layered oxides

Abstract

In the present contribution the effects of doping and coating on the electrochemical performance of layered Na2/3Ni1/2Mn1/2O2 oxide are differentiated. As structural and surface modifiers, we used electrochemically inactive Al3+ ions. The structural modification consists in selective substitution for Ni3+ with Al3+ ion in the transition metal layer. The second approach aims to modify the oxide surface, therefore the pristine oxide as well as aluminium doped one was coated with Al2O3. The distribution of Al3+ ions into the layered crystal structure and Al2O3-coated oxides were monitored by X-ray powder diffraction and EPR spectroscopy. The electrochemical tests were carried out in model two- and three-electrode Swagelok type cells in presence of 1M NaPF6:PC as electrolyte solution and pure sodium metal as counter and reference electrode. Based on the experimental data, it was found that the electrochemical performance of layered Na2/3Ni1/2Mn1/2O2 depends critically on the kind of selected substituents and surface modifiers.

Published

2022

9. High-Performance Layered Oxides for Sodium-Ion Batteries Achieved through Combined Aluminum Substitution and Surface Treatment.

Author

Kalapsazova, Mariya, Kukeva, Rositsa, Harizanova, Sonya, Markov, Pavel, Nihtianova, Diana, Zhecheva, Ekaterina, and Stoyanova, Radostina

Subjects

TRANSITION metal oxides, SURFACE preparation, MANGANESE oxides, NICKEL oxide, OXIDES, ALUMINUM

Abstract

Layered sodium transition metal oxides belong to electrode materials for sodium-ion batteries that combine, in a better way, high performance with environmental requirements. However, their cycling stability is still far from desirable. Herein, we demonstrate a rational approach to control the cycling stability of sodium-deficient nickel manganese oxides, Na2/3Ni1/2Mn1/2O2, with two- and three-layer stacking through Al substitution and Al2O3 treatment. Layered Na2/3Ni1/2Mn1/2O2 oxide displays a limited ability to accommodate aluminum in its structure (i.e., up to 8 at. %). The substitution of Ni ions with electrochemically inactive Al3+ ions and keeping the amount of Mn ions in Na2/3Ni1/2−xAlxMn1/2O2 leads to the stabilization of the two-layer stacking and favors the participation of lattice oxygen in the electrochemical reaction in addition to Ni ions. This results in an increase in the specific capacity of the Al-substituted oxides. Furthermore, the kinetics of the cationic migration between layers occurring during oxide cycling was manipulated by oxide morphology. The best cycling stability is observed for Na2/3Ni0.42Al0.08Mn1/2O2 having a column-like morphology of stacked plate-like particles along the common faces. The treatment of the layered oxides with Al2O3 mitigates the Mn dissolution reaction during electrode cycling in the NaPF6-based electrolyte, thus contributing to a high cycling stability. [ABSTRACT FROM AUTHOR]

Published

2023

10. Electrolyte reactivity at elevated temperature towards P3-Na2/3Ni1/3Mg1/6Mn1/2O2: comparative study of sodium and hybrid lithium-sodium cells

Author

Kalapsazova, Mariya, Markov, Pavel, Kostov, Krassimir, Zhecheva, Ekaterina, Nihtianova, Diana, and Stoyanova, Radostina

Subjects

elevated temperature, sodium layered oxides, sodium-ion batteries, hybrid lithium-sodium batteries, electrolyte reactivity

Abstract

Herein, we demonstrate the temperature-induced reactivity of three-layered oxide: P3-Na2/3Ni1/3Mg1/6Mn1/2O2 (NM16), designed with optimized composition and structure aims to work at elevated temperatures. The electrochemical behavior of P3 Na2/3Ni1/3Mg1/6Mn1/2O2 as a positive electrode is studied in both type of cells – sodium and hybrid lithium-sodium ones, and in presence of conventional carbonate-based and advanced ionic liquids-based (IL) electrolytes. The structural changes and surface reactivity of the layered oxide after cycling are monitored by ex-situ X-ray diffraction (XRD) and X-ray photoelectron spectroscopy (XPS) analyses. In sodium cells the layered structure of P3-NM16 during Na+ intercalation is preserved and any significant phase changes are not observed. It is found that at 40 oC, the rate capability of the oxide is improved upon cycling using an IL electrolyte rather than the carbonate-based electrolyte. The IL electrolyte exhibits a low surface reactivity towards layered oxide, irrespective of the operating temperature. The dominant electrolyte-electrode interaction appears to be the adsorption of the electrolyte ions. In contrast, the carbonate-based electrolyte has been shown to be highly reactive, resulting in the formation of interface rich on inorganic and organic decomposition products. In hybrid Li/Na ion cell, the interaction between P3-NM16 and lithium electrolyte begins before the electrochemical reaction, resulting in a transformation of P3 into O3 type of structure. Along with the structural transformation, a film enriched with LiF, NaF, electrolyte-decomposed products grows on the oxide surface. The film composition depends on the operating temperature and with its increasing the decomposed products become denser. The best cycling stability and rate capability is observed when P3-NM16 operates in hybrid Li/Na ion cell using IL-based electrolyte at 40 oC. In addition the performance of the oxide in hybrid Li/Na ion cell is better than that in single sodium-ion cell which emphasizes the advantage of dual Li+,Na+ ion intercalation.

Published

2021

11. Metal Substitution versus Oxygen-Storage Modifier to Regulate the Oxygen Redox Reactions in Sodium-Deficient Three-Layered Oxides.

Author

Kalapsazova, Mariya, Kukeva, Rositsa, Zhecheva, Ekaterina, and Stoyanova, Radostina

Abstract

Sodium-deficient nickel-manganese oxides with three-layered stacking exhibit the unique property of dual nickel-oxygen redox activity, which allows them to achieve enormous specific capacity. The challenge is how to stabilize the oxygen redox activity during cycling. This study demonstrates that oxygen redox activity of P3-Na2/3Ni1/2Mn1/2O2 during both Na+ and Li+ intercalation can be regulated by the design of oxide architecture that includes target metal substituents (such as Mg2+ and Ti4+) and oxygen storage modifiers (such as CeO2). Although the substitution for nickel with Ti4+ amplifies the oxygen redox activity and intensifies the interaction of oxides with NaPF6- and LiPF6-based electrolytes, the Mg2+ substituents influence mainly the nickel redox activity and suppress the deposition of electrolyte decomposed products (such as MnF2). The CeO2-modifier has a much stronger effect on the oxygen redox activity than that of metal substituents; thus, the highest specific capacity is attained. In addition, the CeO2-modifier tunes the electrode–electrode interaction by eliminating the deposition of MnF2. As a result, the Mg-substituted oxide modified with CeO2 displays high capacity, excellent cycling stability and exceptional rate capability when used as cathode in Na-ion cell, while in Li-ion cell, the best performance is achieved for Ti-substituted oxide modified by CeO2. [ABSTRACT FROM AUTHOR]

Published

2022

12. КОНТРОЛИРАНЕ ПРИ ПОВИШЕНА ТЕМПЕРАТУРА НА ЕЛЕКТРОХИМИЧНИТЕ ХАРАКТЕРИСТИКИ НА P3-Na2/3Ni1/2Mn1/2O2 ЧРЕЗ СЕЛЕКТИВНО ЗАМЕСТВАНЕ НА Ni С Mg

Author

Kalapsazova, Mariya, Markov, Pavel, Kostov, Krassimir, Zhecheva, Ekaterina, Nihtianova, Diana, and Stoyanova, Radostina

Subjects

слоести оксиди, ionic liquids, натриево-йонни батерии, химия на повърхността, sodium-ion batteries, йонни течности, surface chemistry, layered oxides

Abstract

В настоящето изследване ние демонстрираме разработването на състав, който е проектиран да работи при повишени температури. Чрез селективно заместване на Ni2+ йони с Mg2+ в трислойния оксид, P3-Na2/3Ni1/2Mn1/2O2, се контролират степента на окисление на Ni йони, катионно разпределение в слоевете, капацитета на интеркалация на натрий и способността за работа при различни скорости на заряд и разряд. In the present study, we demonstrate the development of a composition that is designed to operate at elevated temperatures. By selective substitution of Ni2+ ions with Mg2+ in the trilayer oxide, P3-Na2/3Ni1/2Mn1/2O2, control the degree of Ni ion oxidation, cation distribution in the layers, the sodium intercalation capacity and the ability to operate at different charge rates and discharge.

Published

2020

13. Controlling at Elevated Temperature the Sodium Intercalation Capacity and Rate Capability of P3‐Na2/3Ni1/2Mn1/2O2 through the Selective Substitution of Nickel with Magnesium.

Author

Kalapsazova, Mariya, Markov, Pavel, Kostov, Krassimir, Zhecheva, Ekaterina, Nihtianova, Diana, and Stoyanova, Radostina

Abstract

The integration of sodium‐ion batteries into large‐scale energy storage systems will become feasible in the case when their performance becomes less sensitive towards ambient temperature. Herein, we demonstrate the elaboration of the oxide‐based electrode material with an optimized layered structure and composition that is designed to work at elevated temperatures. Through selective substitution of Mg2+ ions for Ni2+ in the three‐layered oxide, P3‐Na2/3Ni1/2Mn1/2O2, the oxidation state of Ni ions, the cationic distribution in the layers, the sodium intercalation capacity, and the rate capability is manipulated. The electrochemical behavior of P3‐Na2/3Ni1/3Mg1/6Mn1/2O2 is discussed on the basis of ex situ diffraction as well as microscopic and spectroscopic methods in terms of redox activity of the lattice oxygen, the reversible transfer of Mg2+ and Ni2+ ions between layers during Na+ intercalation, thermal stability of cycled electrodes, and surface reactivity of the layered oxide towards the ionic liquid (IL) electrolyte. At 40 °C, the rate capability of the oxide is improved upon using an IL electrolyte rather than the carbonate‐based electrolyte. [ABSTRACT FROM AUTHOR]

Published

2020