Energy storage materials, Journal Year: 2025, Volume and Issue: unknown, P. 104186 - 104186
Published: March 1, 2025
Language: Английский
Chemical Engineering Journal, Journal Year: 2025, Volume and Issue: unknown, P. 160160 - 160160
Published: Feb. 1, 2025
Language: Английский
Citations
1
Energy storage materials, Journal Year: 2025, Volume and Issue: 76, P. 104098 - 104098
Published: Feb. 7, 2025
Language: Английский
Citations
1
Separation and Purification Technology, Journal Year: 2025, Volume and Issue: unknown, P. 132026 - 132026
Published: Feb. 1, 2025
Language: Английский
Citations
1
Journal of Colloid and Interface Science, Journal Year: 2025, Volume and Issue: 690, P. 137294 - 137294
Published: March 15, 2025
Language: Английский
Citations
0
Small, Journal Year: 2025, Volume and Issue: unknown
Published: March 25, 2025
Vanadium-based materials have shone brightly in aqueous Zn metal batteries due to their high theoretical capacity and excellent high-rate capability. However, the severe vanadium dissolution attacked by H+ during cycling has persistently resulted unsatisfactory stability at low current density (generally ≤0.5 A g-1). To address this critical issue, a reversible H3O+ intercalation chemistry tunnel-structured VO2(B) is herein reported, which activated disordered substitution doping of V4+ W5+/6+ ions while simultaneously introducing oxygen vacancies. Both experiments calculations demonstrate that exhibits stronger adsorption energy on (110) plane synthesized W0.05V0.95O1.94(B) electrode than H+. Moreover, synergy between dopants vacancies can effectively improve distribution sites for H3O+, contributing an enhanced utilization surface-active sites. As result, cathode delivers specific 407 mAh g-1 0.1 maintains 357 with almost no decay after 100 cycles 0.5 g-1. These findings offer promising pathway developing rechargeable long-life vanadium-based cathodes.
Language: Английский
Citations
0
Advanced Functional Materials, Journal Year: 2025, Volume and Issue: unknown
Published: March 25, 2025
Abstract Solid‐state electrolytes are demonstrated great inhibition effect on cathodic dissolution and anodic side reactions in zinc‐ion batteries. In this work, a novel zeolite‐based solid electrolyte (Zeolite‐Zn) enriched with zinc ions, high ionic conductivity (2.54 mS cm −1 ) Zn 2+ transference number (0.866) is prepared through ion‐exchange strategy. Owing to the anhydrous characteristic, Zeolite‐Zn effectively extends electrochemical window 2.5 V inhibits hydrogen evolution reaction. As for Zn||Zeolite‐Zn||NH 4 O 10 batteries, high‐capacity retention rate of 84.9% can be achieved after 1010 cycles at 0.5 A g . Even temperature 60 °C, NH cathode able maintain reversible capacity 239.2 mAh 110 cycles, which attributed superior structural stability, weak interfacial reaction, low migration barrier, inhibited vanadium electrolyte. addition, as‐fabricated Zn||Zeolite‐Zn||AC@I 2 batteries have also brilliant performances, suggesting its promising potential practical application zinc‐based secondary This study provides mechanistic insights inspiration original design inorganic electrolytes.
Language: Английский
Citations
0
ACS Sustainable Chemistry & Engineering, Journal Year: 2025, Volume and Issue: unknown
Published: April 2, 2025
Language: Английский
Citations
0
Chemical Engineering Journal, Journal Year: 2025, Volume and Issue: unknown, P. 162606 - 162606
Published: April 1, 2025
Language: Английский
Citations
0
Journal of Energy Storage, Journal Year: 2025, Volume and Issue: 122, P. 116596 - 116596
Published: April 15, 2025
Citations
0
Journal of Power Sources, Journal Year: 2025, Volume and Issue: 644, P. 237073 - 237073
Published: April 22, 2025
Language: Английский
Citations
0