Impedance Analysis with Transmission Line Model for Reaction Distribution in a Pouch Type Lithium-Ion Battery by Using Micro Reference Electrode

Nara, Hiroki; Mukoyama, Daikichi; Yokoshima, Tokihiko; Momma, Toshiyuki; Osaka, Tetsuya

doi:10.1149/2.0341603jes

Cited by 62 publications

(41 citation statements)

References 52 publications

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“…18,21 In order to study electrode ageing mechanisms, Transmission Line Models (TLMs; a subset of ECMs) have previously been used to model the impedance response of porous electrodes infiltrated by a liquid electrolyte. 15,20,22,23 One important ability of these TLMs is the calculation of ionic resistance in the infiltrated pores R ion,L . The electronic resistance R el through the composite electrode is usually considered negligible compared to the ionic resistance.…”

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confidence: 99%

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Scipioni¹,

Jørgensen²,

Graves³

et al. 2017

J. Electrochem. Soc.

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In this work an Equivalent Circuit Model (ECM) is developed and used to model impedance spectra measured on a commercial 26650 LiFePO 4 /Graphite cylindrical cell. The ECM is based on measurements and modeling of impedance spectra recorded separately on cathode (LiFePO 4 ) and anode (Graphite) samples, harvested from the commercial cell. Modeling of the single-electrode impedance spectra provided information about the electronic and ionic resistance in the porous composite electrodes, as well as the solid state diffusion. Focused Ion Beam (FIB)/Scanning Electron Microscopy (SEM) of anode and cathode samples was used to make 3-D maps of the electrode microstructures and to obtain microstructural data for the ECM. The cylindrical cell continues to be one of the most widely used packaging styles for primary and secondary batteries. The advantages are ease of manufacture and good mechanical stability. The tubular cylinder can withstand high internal pressures without deforming.

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confidence: 99%

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Scipioni¹,

Jørgensen²,

Graves³

et al. 2017

J. Electrochem. Soc.

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“…At all the spectra, semicircles or collapsed semicircles are observed in the high frequency region of >100 Hz, indicating charge transfer through the surface film formed on the anode and cathode. 39,40 The resistance derived from these films increased with increasing cycle numbers. In the low frequency region, which is considered to be related to the solid state diffusion of lithium ion in the electrode bulk, 41 a linear line at 100th cycle changes into a part of collapsed semicircle at 400th cycle, indicating that the lithium ion diffusion is gradually inhibited with increasing cycle numbers.…”

Section: Resultsmentioning

confidence: 99%

Surface State Change of Lithium Metal Anode in Full Cell during Long Term Cycles

et al. 2019

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In order to investigate the surface state change of the lithium metal anode during long term cycles, a laminate-type lithium metal rechargeable battery was fabricated from a lithium foil, a Li 4 Mn 5 O 12 electrode, a polyimide (PI) membrane having a three-dimensionally ordered macroporous structure (3DOM) and a 1 mol dm −3 LiPF 6 ethylene carbonate (EC) solution as an anode, a cathode, a separator and an electrolyte, respectively. After the charge/ discharge cycles, the chemical composition at the surface of the lithium metal anode taken from the laminate cell was investigated by X-ray photoelectron spectroscopy (XPS). Decomposition products of electrolyte, e.g. Licontaining organic compounds, LiF or-PO 4 were accumulated on the lithium metal surface during long-term charge/discharge cycles. The accumulation of the decomposition products causes the increase of the lithium ion transport resistance of the battery, resulting in the inhibition of dissolution and deposition of lithium which is associated with drop of capacity.

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“…As mentioned above, EIS is the method of choice to study the electrochemical properties of various battery electrodes as a function of cycling or state of charge [54]. Positive electrode active materials including V6O13 [14,55], LiMn2O4 [56,57] [72,73], LiNi0.5Mn1.5O4 [74], LiNi0.5Mn0.3Co0.2O2 [36,75], and LiNi0.6Mn0.6Co0.2O2 [76], as well as negative electrode active materials, such as carbons [35,60,68,[77][78][79][80], graphite [16,31,[36][37][38]57,[62][63][64][65][66][67][68][69][70][71][72][73][74][75]81,82], Sn-containing composites [82,83], LiTi2(PO4)3 [15], Li4Ti5O12 [61], and Si-containing composites [34,84,85] have...…”

Section: Electrochemical Impedance-based Techniquesmentioning

confidence: 99%

“…It has also been reported that overcharge conditions produce a high impedance at the positive electrode, while over discharge of the battery results in a higher impedance at the negative electrode [72]. Interestingly, when metallic Li is used as the negative electrode instead of a In general, three-electrode measurements have shown that the main contribution to the impedance of a LIB cell originates from the positive electrode [37,63,71,73,81]. The negative electrode, which generally comprises a graphitic active material, commonly exhibits a stable impedance contribution independent of the state of charge of the battery [63,71,73].…”

Section: Electrochemical Impedance-based Techniquesmentioning

confidence: 99%

Critical Review of the Use of Reference Electrodes in Li-Ion Batteries: A Diagnostic Perspective

2019

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Use of a reference electrode (RE) in Li-ion batteries (LIBs) aims to enable quantitative evaluation of various electrochemical aspects of operation such as: (i) the distinct contribution of each cell component to the overall battery performance, (ii) correct interpretation of current and voltage data with respect to the components, and (iii) the study of reaction mechanisms of individual electrodes. However, care needs to be taken to ensure the presence of the RE does not perturb the normal operation of the cell. Furthermore, if not properly controlled, geometrical and chemical features of the RE can have a significant influence on the measured response. Here, we present a comprehensive review of the range of RE types and configurations reported in the literature, with a focus on critical aspects such as electrochemical methods of analysis, cell geometry, and chemical composition of the RE and influence of the electrolyte. Some of the more controversial issues reported in the literature are highlighted and the benefits and drawbacks of the use of REs as an in situ diagnostic tool in LIBs are discussed.

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Impedance Analysis with Transmission Line Model for Reaction Distribution in a Pouch Type Lithium-Ion Battery by Using Micro Reference Electrode

Cited by 62 publications

References 52 publications

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

Surface State Change of Lithium Metal Anode in Full Cell during Long Term Cycles

Critical Review of the Use of Reference Electrodes in Li-Ion Batteries: A Diagnostic Perspective

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Impedance Analysis with Transmission Line Model for Reaction Distribution in a Pouch Type Lithium-Ion Battery by Using Micro Reference Electrode

Cited by 62 publications

References 52 publications

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO4/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO4/Graphite 26650 Cylindrical Cell

Surface State Change of Lithium Metal Anode in Full Cell during Long Term Cycles

Critical Review of the Use of Reference Electrodes in Li-Ion Batteries: A Diagnostic Perspective

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Product

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A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell

A Physically-Based Equivalent Circuit Model for the Impedance of a LiFePO₄/Graphite 26650 Cylindrical Cell