Journal
NANO ENERGY
Volume 89, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.nanoen.2021.106322
Keywords
Zinc-ion batteries; Anode; Cellulose separator; ZrO2; Dendrites-free
Categories
Funding
- Second Century Fund (C2F), Chulalongkorn University
- National Research Council of Thailand (NRCT) [NRCT-RSA63001-19]
- Guangdong Innovative & Entrepreneurial Research Team Program [2016ZT06C279]
- Shenzhen Peacock Plan [KQTD2016053019134356]
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A cellulose nanofibers-ZrO2 composite separator (ZC) has been developed to stabilize the zinc anode in aqueous zinc-ion batteries, enabling excellent ionic conductivity and high Zn2+ transfer number. The ZrO2 particles with high dielectric constant offer a directional electric field to regulate uniform zinc deposition, accelerate Zn2+ ions diffusion kinetics, and repel anions, resulting in dendrite-free plating/stripping behavior, high Coulombic efficiency and exceptional cyclability for the zinc anode.
The optimization strategies of electrode and electrolyte currently advocated for zinc dendrite suppression remain challenging for aqueous zinc-ion batteries (ZIBs) due to their complex manufacturing processes and noneconomic prices. Here, a cellulose nanofibers-ZrO2 composite (ZC) separator with easily-fabricated and costeffective features is developed to stabilize the zinc anode. The ZC separator is designed to enable excellent ionic conductivity (4.59 mS cm(-1)) and high Zn2+ transfer number (0.69), and the ZrO2 particles with high dielectric constant (epsilon = 25) offer a directional electric field via the Maxwell-Wagner polarization effect, which regulates uniform zinc deposition, accelerate the Zn2+ ions diffusion kinetics and repel anions, thus stabilizing zinc anode and suppressing passivation reactions. As a result, ZC separator renders zinc anode with dendrite-free plating/stripping behavior, high Coulombic efficiency (99.5%) and exceptional cyclability (2000 h under 0.5 mA cm(-2)). Additionally, this developed composite separator can be extended to other insulating ceramics, or even random combinations. Moreover, the rate capability and cyclability of the as-assembled Zn parallel to ZnSO4 parallel to MnO2/graphite coin and pouch cells also can be significantly boosted via the ZC separator, accompanied by the remarkable flexibility and integration ability. The ceramics-cellulose separators offer an appealing strategy for constructing advanced zinc anode for large-scale energy storage.
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