Measuring the Parasitic Heat Flow of Lithium Ion Pouch Cells Containing EC-Free Electrolytes

Glazier, Stephen; Petibon, R.; Xia, Jian; Dahn, J. R.

doi:10.1149/2.0331704jes

Cited by 22 publications

(25 citation statements)

References 33 publications

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“…42,46 Since the entropic heat flow is reversible between charge and discharge, the average parasitic heat flow at each voltage point can be found by taking the average of charge and discharge heat flow and subtracting the average overpotential heat flow. The details of this method was introduced by S. Glazier et al 47 Figure 8a • C were observed for all the charged electrode materials and the peak intensity increases with increasing of state of charge of the electrode materials (higher upper cutoff voltage of the cells). The release of oxygen from the bulk of the charged materials is associated with the degradation of NMC532 from a layered (Li x MO 2 , M = Ni, Mn and Co) structure to a rock-salt (Li x M 1-x O) structure.…”

Section: Resultsmentioning

confidence: 99%

Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

Cameron

et al. 2017

J. Electrochem. Soc.

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325

286

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Single-crystal LiNi 0.5 Mn 0.3 Co 0.2 O 2 (NMC532) with a grain size of 2-3 μm was compared to conventional polycrystalline uncoated NMC532 and polycrystalline Al 2 O 3 -coated materials in this work. Studies were made to determine how single crystal NMC532 material with large grain size could be synthesized. Ultra high precision coulometry (UHPC), in-situ gas measurements and isothermal microcalorimetry were used to make comparative studies of the three materials in Li-ion pouch cells. All the diagnostic measurements suggested that the single crystal material should yield Li-ion cells with longer lifetime. Long-term cycling tests verified these predictions and showed that cells with single crystal NMC532 exhibited much better capacity retention than cells with the polycrystalline materials at both 40 • C and 55 • C when tested to an upper cutoff potential of 4.4 V. The reasons for the superior performance of the single crystal cells were explored using thermogravimetric analysis/mass spectrometry experiments on the charged electrode materials. The single crystal materials were extremely resistant to oxygen loss below 100 • C compared to the polycrystalline materials. The major drawback of the single crystal material is its slightly lower specific capacity compared to the polycrystalline materials. However, this may not be an issue for Li-ion cells designed for long lifetime applications. Lithium ion batteries with high energy density, long lifetime and low cost need to be developed for applications in electric vehicles and stationary energy storage. The family of Li(Ni x Mn y Co z )O 2 (x + y + z = 1) (NMC) materials with high nickel and low cobalt are used as positive electrode materials in lithium ion cells.1,2 One simple way to increase the energy density of NMC lithium ion cells is to increase their upper cutoff voltage which gives access to higher specific capacity from the positive electrode.3,4 However, increasing the upper cutoff voltage usually decreases the lifetime of cells due to an acceleration of 'unwanted' parasitic reactions between the electrolyte and the delithiated positive electrode surface at high voltages. Such reactions include oxidation of species found in the electrolyte, transition metal dissolution, etc. [5][6][7] In addition, structural reconstruction of the positive electrode surface can occur which can contribute to impedance growth and capacity loss. 3,4 The by-products of oxidation at the positive electrode can migrate to the negative electrode surface and be reduced there. 8,9 Such reactions can lead to the consumption of lithium ions from the electrolyte, (to maintain charge neutrality in the electrolyte), a reduction in lithium inventory, as well as a thickening of the negative electrode solid electrolyte interface (SEI) which together ultimately cause cell-failure.10,11 These processes are accelerated by higher charging potentials and higher temperatures.Methods such as modification of the positive electrode surface with coatings or dopants 12,13 and/or modification of electr...

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Section: Resultsmentioning

confidence: 99%

Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

Cameron

et al. 2017

J. Electrochem. Soc.

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325

286

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“…However, these cathodes suffer from poor cyclability and thermal abuse tolerance due to their high reactivity with the commonly used ethylene carbonate (EC)‐based electrolyte solution. [ 7–11 ] As well recognized, the EC‐based electrolyte is easily oxidized on the surfaces of high nickel cathodes at high voltages, resulting in electrolyte dryout, gas evolution, and impedance growth and consequently a continuous degradation of battery performance. [ 12–14 ] On the other hand, the high melting point of EC is a major cause for the poor low temperature performance of current LIBs.…”

Section: Introductionmentioning

confidence: 99%

“…Recent works have demonstrated that simply removal of EC from the currently used electrolytes can enable considerably improved high‐voltage cyclability and high temperature stability of LIBs. [ 9,10,12–15 ] Therefore, development of advanced electrolyte systems is crucial for overcoming the challenges of conventional EC‐based electrolyte on new LIB electrodes.…”

Section: Introductionmentioning

confidence: 99%

Ethylene Carbonate‐Free Propylene Carbonate‐Based Electrolytes with Excellent Electrochemical Compatibility for Li‐Ion Batteries through Engineering Electrolyte Solvation Structure

Liu

Shen

et al. 2021

Advanced Energy Materials

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Propylene carbonate (PC) ‐based electrolytes have many desirable advantageous properties compared to the currently used ethylene carbonate (EC) ‐based electrolytes for lithium ion batteries, however, their poor compatibility with the graphite anode hinders its applications. Here, a facile and effective strategy to make electrochemically compatible PC‐based electrolytes by use of a weakly coordinating diethyl carbonate co‐solvent to induce PF6− anions into the solvation shell of Li+ to form an anion‐induced ion–solvent‐coordinated (AI‐ISC) structure is reported. Such an AI‐ISC structure can lead to an increase of the lowest unoccupied molecular orbital energy level of the electrolyte, therefore considerably improving the reduction tolerance of the PC solvent. Furthermore, by using the film‐forming additive (fluoroethylene carbonate, FEC), an electrochemically stable, EC‐free PC‐based electrolyte, which enables reversible Li+ intercalation on the graphite electrode is obtained. The graphite/LiNi0.5Mn0.3Co0.2O2 pouch cells using this PC‐based electrolyte exhibit very similar room‐temperature electrochemical performance to those using conventional EC‐based electrolytes and excellent low‐temperature performance. This work provides a new approach to make EC‐free electrolytes with a similar AI‐ISC structure but without the need for a high concentration of Li salt of highly concentrated electrolytes, which may bring new insights in the development of advanced electrolyte systems for wide battery applications.

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“…This method has been used to determine the benefit of removing EC from NMC442/graphite cells above 4.3 V, 27,28 as well as measuring the effect of vinylene carbonate and 1-fluoro-ethlyne carbonate as electrolyte additives on the parasitic heat flow in large voltage ranges. 29 Figure 4a demonstrates this method to calculate the parasitic heat flow of one of the 442 cells during the first protocol step between 3.9 V and 4.2 V and will be called the "average method" throughout this work.…”

Section: Resultsmentioning

confidence: 99%

The Effect of Different Li(Ni_1-x-yMn_xCo_y)O₂Positive Electrode Materials and Coatings on Parasitic Heat Flow as Measured by Isothermal Microcalorimetry, Ultra-High Precision Coulometry and Long Term Cycling

Glazier

Nelson

Allen

et al. 2017

J. Electrochem. Soc.

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Isothermal microcalorimetry is used to investigate the effect of different Li(Ni 1-x-y Mn x Co y )O 2 materials (NMC442, NMC532, NMC622) and coatings (Al 2 O 3 and a proprietary high voltage coating) on parasitic reactions that occur in Li-ion pouch type cells. NMC/graphite pouch cells were prepared with a typical organic carbonate-based electrolyte containing a well-known additive blend and were tested up to 4.4 V at 40 • C. A new method of extracting the parasitic heat flow during both charge and discharge is introduced. Differences between charge and discharge parasitic heat flow yielded more insight into the behavior of high voltage parasitic reactions. Ultra-high precision coulometry, long-term charge discharge cycling, in-situ gas measurements, and electrochemical impedance spectroscopy were also used to compare the observed heat flow to well-known performance metrics. All coated cell types performed significantly better than uncoated NMC442/graphite cells. It was found that the magnitude of the parasitic heat flows did not correlate as expected to the precision coulometry results nor to the long term cycling results. In particular, cells with Al 2 O 3 -coated NMC622 had the highest parasitic heat flow among the cells with coated electrodes but competed for best performance in the cycling tests. High voltage lithium ion batteries have become a focus of academic and industrial research in order to meet the increasing demand for high energy density, low cost and long lifetime energy storage applications. In order to increase the operational voltage of lithium ion cells, all components must be as electrochemically stable as possible in order to prevent unwanted parasitic reactions within the cell, especially at high potentials. Arguably one of the most effective solutions to minimizing parasitic reactions and improving cell lifetime has been the addition of small amounts of additives to typical electrolytes already used in research and industry.1-3 These additives typically: are incorporated at a few percent by weight, introduce little to no change in the manufacturing process, and form protective passivating films known as the solid-electrolyte interphases (SEI) on both the positive and negative electrodes during cell operation. Although extensively studied, the mechanisms and chemical pathways responsible for the SEI films and the observed changes in performance caused by electrolyte additives are relatively poorly understood.Another common technique to reduce parasitic reactions is to alter the electrode materials in order to create a more electrochemically stable interface between the electrolyte and the highly delithiated positive electrode during high voltage operation. Metal oxide surface coatings such as Al 2 O 3 have been found to improve the stability of this interface, mitigate electrolyte oxidation, improve cycling performance and scavenge HF.4-8 Selected ratios of transition metals in Li(Ni 1-x-y Mn x Co y )O 2 (NMC) positive electrodes can also lower the reactivity of the electrode surface with ...

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Measuring the Parasitic Heat Flow of Lithium Ion Pouch Cells Containing EC-Free Electrolytes

Cited by 22 publications

References 33 publications

Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

Ethylene Carbonate‐Free Propylene Carbonate‐Based Electrolytes with Excellent Electrochemical Compatibility for Li‐Ion Batteries through Engineering Electrolyte Solvation Structure

The Effect of Different Li(Ni_1-x-yMn_xCo_y)O₂Positive Electrode Materials and Coatings on Parasitic Heat Flow as Measured by Isothermal Microcalorimetry, Ultra-High Precision Coulometry and Long Term Cycling

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Measuring the Parasitic Heat Flow of Lithium Ion Pouch Cells Containing EC-Free Electrolytes

Cited by 22 publications

References 33 publications

Comparison of Single Crystal and Polycrystalline LiNi0.5Mn0.3Co0.2O2Positive Electrode Materials for High Voltage Li-Ion Cells

Comparison of Single Crystal and Polycrystalline LiNi0.5Mn0.3Co0.2O2Positive Electrode Materials for High Voltage Li-Ion Cells

Ethylene Carbonate‐Free Propylene Carbonate‐Based Electrolytes with Excellent Electrochemical Compatibility for Li‐Ion Batteries through Engineering Electrolyte Solvation Structure

The Effect of Different Li(Ni1-x-yMnxCoy)O2Positive Electrode Materials and Coatings on Parasitic Heat Flow as Measured by Isothermal Microcalorimetry, Ultra-High Precision Coulometry and Long Term Cycling

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Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

Comparison of Single Crystal and Polycrystalline LiNi_0.5Mn_0.3Co_0.2O₂Positive Electrode Materials for High Voltage Li-Ion Cells

The Effect of Different Li(Ni_1-x-yMn_xCo_y)O₂Positive Electrode Materials and Coatings on Parasitic Heat Flow as Measured by Isothermal Microcalorimetry, Ultra-High Precision Coulometry and Long Term Cycling