Aqueous zinc ion batteries based on sodium vanadate electrode materials with long lifespan and high energy density

Abstract: We have prepared Na7V7.6O20·4H2O (NVO) nanobelts by a facile hydrothermal route. The assembled NVO/Zn batteries deliver a capacity of 309.4 mA h g−1 at 0.3 A g−1 and maintain excellent cycling stability after 10 000 cycles at 10 A g−1.

“…When discharged to 0.2 V, the Zn 2p peaks present strong signals at 1022.6 eV (2p 3/2 ) and 1045.7 eV (2p 1/2 ). The peaks of Zn 2p are significantly weakened in the charging process, suggesting the presence of residual Zn 2+ …”

“…The peaks of Zn 2p are significantly weakened in the charging process, suggesting the presence of residual Zn 2+ . 45 TEM is employed to further investigate the morphological change of the electrodes. The microsphere structure of the VO 2 @C-0.5 electrode is still maintained during cycling (Figure 6e,g).…”

Enhanced Electrochemical Performance of Zn/VO_x Batteries by a Carbon-Encapsulation Strategy

“…When discharged to 0.2 V, the Zn 2p peaks present strong signals at 1022.6 eV (2p 3/2 ) and 1045.7 eV (2p 1/2 ). The peaks of Zn 2p are significantly weakened in the charging process, suggesting the presence of residual Zn 2+ …”

“…The peaks of Zn 2p are significantly weakened in the charging process, suggesting the presence of residual Zn 2+ . 45 TEM is employed to further investigate the morphological change of the electrodes. The microsphere structure of the VO 2 @C-0.5 electrode is still maintained during cycling (Figure 6e,g).…”

Enhanced Electrochemical Performance of Zn/VO_x Batteries by a Carbon-Encapsulation Strategy

“…[10][11][12][13][14] Among numerous multivalent ion systems, AZIBs possess a large theoretical capacity of 820 mA h g −1 . 15,16 However, it is challenging to search for suitable cathode materials with excellent stability in water solution. 17 Some progress has been made, including manganese-based oxides, Prussian blue analogs, and vanadium-based materials.…”

Ammonium vanadate electrode materials with stable layered structures for rechargeable zinc ion batteries

“…At present, the demand for clean energy resources has become overwhelming due to superfluous carbon emission. [1][2][3] As an emerging energy storage device, a supercapacitor not only fills the gap between traditional capacitors and batteries, but also shows many advantages, such as a wide working temperature range and long cycle life. [4][5][6] However, its relatively low energy density hinders its further application.…”

Transition metal sulfide/hydroxide electrode materials with high specific capacities