Journal
ENERGY STORAGE MATERIALS
Volume 43, Issue -, Pages 202-211Publisher
ELSEVIER
DOI: 10.1016/j.ensm.2021.08.044
Keywords
Batteries; Nanofluidics; Nanoparticles; Compact electrode; Energy density
Funding
- Australian Re-search Council Discovery Project [DP190101008, FT190100058]
- UNSW Scientia Program
- UNSW Scientia PhD Scholarship
- UNSW Research Infrastructure Scheme
Ask authors/readers for more resources
By adding nanofluidic additives, unimpeded ion transport can be achieved in nanoparticle electrodes, maintaining high density of the electrodes while improving volumetric capacity of the batteries. The use of nanofluidic-enhanced dense electrodes can enhance the performance of lithium-ion batteries, and this approach can be extended to various electroactive nanoparticles in battery design.
Nanosized materials are widely applied in lithium-ion battery to improving power/energy performances. However, the low packing density of nanoparticles limits the volumetric capacity of electrodes. Calendering nanoparticle electrodes leads to pore destruction, electrolyte blocking and poor ion transport. This work reports unimpeded ion transport in ultracompact nanoparticle electrodes by nanofluidic additives that provide rapid ion pathways without loss of electrode density. Sub-micron commercial LiFePO4 particles, as a model cathode material, are deployed to fabricate the nanofluidic-enhanced dense electrodes that show excellent volumetric capacities in liquid and gel polymer electrolytes, which surpass state-of-the-art LiFePO4 electrodes. This extraordinary performance (303.6 mAh cm(-3) and 1026.2 Wh L-1 at 0.06 C) correlates with the conductive nanofluidic network through which lithium ions can move around swiftly. This nanofluidic strategy can be extended to other electroactive nanoparticles in the design of high-capacity compact batteries.
Authors
I am an author on this paper
Click your name to claim this paper and add it to your profile.
Reviews
Recommended
No Data Available