Hyunsang Joo scite author profile

The localisation and quantitative analysis of lithium (Li) in battery materials, components, and full cells are scientifically highly relevant, yet challenging tasks. The methodical developments of MeV ion beam analysis (IBA) presented here open up new possibilities for simultaneous elemental quantification and localisation of light and heavy elements in Li and other batteries. It describes the technical prerequisites and limitations of using IBA to analyse and solve current challenges with the example of Li-ion and solid-state battery-related research and development. Here, nuclear reaction analysis and Rutherford backscattering spectrometry can provide spatial resolutions down to 70 nm and 1% accuracy. To demonstrate the new insights to be gained by IBA, SiOx-containing graphite anodes are lithiated to six states-of-charge (SoC) between 0–50%. The quantitative Li depth profiling of the anodes shows a linear increase of the Li concentration with SoC and a match of injected and detected Li-ions. This unambiguously proofs the electrochemical activity of Si. Already at 50% SoC, we derive C/Li = 5.4 (< LiC6) when neglecting Si, proving a relevant uptake of Li by the 8 atom % Si (C/Si ≈ 9) in the anode with Li/Si ≤ 1.8 in this case. Extrapolations to full lithiation show a maximum of Li/Si = 1.04 ± 0.05. The analysis reveals all element concentrations are constant over the anode thickness of 44 µm, except for a ~6-µm-thick separator-side surface layer. Here, the Li and Si concentrations are a factor 1.23 higher compared to the bulk for all SoC, indicating preferential Li binding to SiOx. These insights are so far not accessible with conventional analysis methods and are a first important step towards in-depth knowledge of quantitative Li distributions on the component level and a further application of IBA in the battery community.

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Cell manipulation systems using dielectrophoretic process for diagnostic sensors

Joo

Kim

Cha

et al. 2012

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This paper demonstrated the effectiveness of Dielectrophoresis (DEP) on microfluidic devices as part of diagnostic sensors. It was possible to focus bacterial cells into the intended area based on droplet evaporation on hydrophobic guide structure and DEP force with micro-patterned electrodes. Similarly, we dealt with separation of blood cells from whole blood so that plasma can be applied in many biomedical fields. The micro fluidic channels were attached on both sides of the device which includes electrodes for DEP and pore-array membrane. Micro-sized beads were experimented prior to realizing those two functions of DEP on biological cells.

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Hyunsang Joo

Electrokinetic separation of biomolecules through multiple nano-pores on membrane

Quantitative Lithiation Depth Profiling in Silicon Containing Anodes Investigated by Ion Beam Analysis

Cell manipulation systems using dielectrophoretic process for diagnostic sensors

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