Abstract
As a concept for electrode architecture in high power lithium ion batteries, self-supported nanoarrays enable ultra-high power densities as a result of their open pore geometry, which results in short and direct Li+-ion and electron pathways. Vertically aligned carbon nanotubes (VACNT) on metallic current collectors with low interface resistance are used as current collectors for the chemical solution infiltration of electroactive oxides to produce vertically aligned carbon nanotubes decorated with in situ grown LiMn2O4 (LMO) and Li4Ti5O12 (LTO) nanoparticles. The production processes steps (catalyst coating, VACNT chemical vapor deposition (CVD), infiltration, and thermal transformation) are all scalable, continuous, and suitable for niche market production to achieve high oxide loadings up to 70 wt %. Due to their unique transport structure, as-prepared nanoarrays achieve remarkably high power densities up to 2.58 kW kg−1, which is based on the total electrode mass at 80 C for LiMn2O4//Li4Ti5O12 full cells. The tailoring of LTO and LMO nanoparticle size (~20–100 nm) and VACNT length (array height: 60–200 µm) gives insights into the rate-limiting steps at high current for these kinds of nanoarray electrodes at very high C-rates of up to 200 C. The results reveal the critical structural parameters for achieving high power densities in VACNT nanoarray full cells.
Highlights
The development of lithium ion batteries (LIB) that enable fast charging combined with high safety and a long cycle life is crucial for their applications in the fields of mobile electronic devices and hybrid electric vehicles [1,2]
The in situ synthesis of LiMn2 O4 (LMO) on vertically aligned carbon nanotubes (VACNT) requires the oxidation of manganese (II)
The synthesis is performed in air, which potentially facilitates carbon nanotubes nanotubes (CNT) oxidation, and in consequence leads to decreased electron conductivity
Summary
The development of lithium ion batteries (LIB) that enable fast charging combined with high safety and a long cycle life is crucial for their applications in the fields of mobile electronic devices and hybrid electric vehicles [1,2]. Longgrain ion produced in this way usually suffer from largeconductive internal electrical resulting from the diffusion pathways, limited electron transport through percolating networklong of the electronboundaries between electroactive material, conductive agent,aand binder. The vertical alignment direct pathways electron between the electrode material and the current collector reduces induces charge transfer resistances.forMoreover, transport, heavily reduce the amount for of electron phase boundaries, and allows fast the vertical which alignment induces direct pathways transport, which heavily reduce thevery amount electron transport.
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