Your search keyword '"Averianov, Timofey"' showing total 2 results

1. Vanadium and Niobium MXenes—Bilayered V2O5 Asymmetric Supercapacitors.

Author

Saraf, Mohit, Zhang, Teng, Averianov, Timofey, Shuck, Christopher E., Lord, Robert W., Pomerantseva, Ekaterina, and Gogotsi, Yury

Subjects

ENERGY storage, NIOBIUM, NEGATIVE electrode, CARBON composites, CARBON nanotubes, SUPERCAPACITORS, VANADIUM

Abstract

MXenes offer high metallic conductivity and redox capacitance that are attractive for high‐power, high‐energy storage devices. However, they operate limitedly under high anodic potentials due to irreversible oxidation. Pairing them with oxides to design asymmetric supercapacitors may expand the voltage window and increase the energy storage capabilities. Hydrated lithium preintercalated bilayered V2O5 (δ‐LixV2O5·nH2O) is attractive for aqueous energy storage due to its high Li capacity at high potentials; however, its poor cyclability remains a challenge. To overcome its limitations and achieve a wide voltage window and excellent cyclability, it is combined with V2C and Nb4C3 MXenes. Asymmetric supercapacitors employing lithium intercalated V2C (Li‐V2C) or tetramethylammonium intercalated Nb4C3 (TMA‐Nb4C3) MXenes as the negative electrode, and a δ‐LixV2O5·nH2O composite with carbon nanotubes as the positive electrode in 5 m LiCl electrolyte operate over wide voltage windows of 2 and 1.6 V, respectively. The latter shows remarkably high cyclability—capacitance retention of ≈95% after 10 000 cycles. This work highlights the importance of selecting appropriate MXenes to achieve a wide voltage window and a long cycle life in combination with oxide anodes to demonstrate the potential of MXenes beyond Ti3C2 in energy storage. [ABSTRACT FROM AUTHOR]

Published

2023

2. Phase transformation and electrochemical charge storage properties of vanadium oxide/carbon composite electrodes synthesized via integration with dopamine.

Author

Andris, Ryan, Averianov, Timofey, and Pomerantseva, Ekaterina

Subjects

*ELECTROCHROMIC devices, *CARBON composites, *VANADIUM oxide, *CARBON electrodes, *PHASE transitions, *DOPAMINE, *VANADIUM

Abstract

Chemically preintercalated dopamine (DOPA) molecules were used as both a reducing agent and a carbon precursor to prepare δ‐V2O5·nH2O/C, H2V3O8/C, VO2(B)/C, and V2O3/C nanocomposites via hydrothermal treatment or hydrothermal treatment followed by annealing under Ar flow. We found that the phase composition and morphology of the produced composites are influenced by the DOPA:V2O5 ratio used to synthesize (DOPA)xV2O5 precursors through DOPA diffusion into the interlayer region of the δ‐V2O5·nH2O framework. The increase of DOPA concentration in the reaction mixture led to a more pronounced reduction of vanadium and a higher fraction of carbon in the composites' structure, as evidenced by X‐ray photoelectron spectroscopy and Raman spectroscopy measurements. The electrochemical charge storage properties of the synthesized nanocomposites were evaluated in Li‐ion cells with nonaqueous electrolytes. δ‐V2O5·nH2O/C, H2V3O8/C, VO2(B)/C, and V2O3/C electrodes delivered high initial capacities of 214, 252, 279, and 637 mAh g–1, respectively. The insights provided by this investigation open up the possibility of creating new nanocomposite oxide/carbon electrodes for a variety of applications, such as energy storage, sensing, and electrochromic devices. [ABSTRACT FROM AUTHOR]

Published

2023