Effects of Dissolved Transition Metals on the Electrochemical Performance and SEI Growth in Lithium-Ion Batteries

Joshi, Tapesh; Eom, KwangSup; Yushin, Gleb; Fuller, Thomas F.

doi:10.1149/2.0861412jes

Cited by 164 publications

(172 citation statements)

References 51 publications

(106 reference statements)

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“…This is expected, considering that the dissolution of Mn from the NMC cathode is highly temperature dependent. The presence of Mn on the LTO electrodes should originate from manganese, which have been dissolved from the NMC electrode, and is in good agreement with the well‐known aging mechanism in LIB cells …”

Section: Resultssupporting

confidence: 82%

Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

et al. 2019

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Aging mechanisms in lithium‐ion batteries are dependent on the operational temperature, but the detailed mechanisms on what processes take place at what temperatures are still lacking. The electrochemical performance and capacity fading of the common cell chemistry LiNi1/3Mn1/3Co1/3O2 (NMC)/Li4Ti5O12 (LTO) pouch cells are studied at temperatures 10, 30, and 55 °C. The full cells are cycled with a moderate upper cutoff potential of 4.3 V versus Li+/Li. The electrode interfaces are characterized postmortem using photoelectron spectroscopy techniques (soft X‐ray photoelectron spectroscopy [SOXPES], hard X‐ray photoelectron spectroscopy [HAXPES], and X‐ray absorption near edge structure [XANES]). Stable cycling at 30 °C is explained by electrolyte reduction forming a stabilizing interphase, thereby preventing further degradation. This initial reaction, between LTO and the electrolyte, seems to be beneficial for the NMC–LTO full cell. At 55 °C, continuous electrolyte reduction and capacity fading are observed. It leads to the formation of a thicker surface layer of organic species on the LTO surface than at 30 °C, contributing to an increased voltage hysteresis. At 10 °C, large cell‐resistances are observed, caused by poor electrolyte conductivity in combination with a relatively thicker and LixPFy‐rich surface layer on LTO, which limit the capacity.

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Section: Resultssupporting

confidence: 82%

Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

et al. 2019

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“…[11][12][13]18,51 To examine the extent of transition metal deposition on the anode, PGAA was used to quantify the amount of deposited Ni, Mn, Co on harvested graphite anodes. Due to the large penetration depth of neutrons, PGAA examines the entire volume of the investigated anode samples.…”

Section: Ex Situ Xrd Analysis Of Aged Nmc Electrodes-mentioning

confidence: 99%

Aging Analysis of Graphite/LiNi_1/3Mn_1/3Co_1/3O₂Cells Using XRD, PGAA, and AC Impedance

Buchberger

Seidlmayer

Pokharel

et al. 2015

J. Electrochem. Soc.

217

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The performance degradation of graphite/LiNi 1/3 Mn 1/3 Co 1/3 O 2 (NMC) lithium ion cells, charged and discharged up to 300 cycles at different operating conditions of temperature and upper cutoff potential (4.2V/25 • C, 4.2V/60 • C, 4.6V/25 • C) was investigated. A combination of electrochemical methods with X-ray diffraction (XRD) both in situ and ex situ as well as neutron induced PromptGamma-Activation-Analysis (PGAA) allowed us to elucidate the main failure mechanisms of the investigated lithium ion cells. In situ XRD investigations of the NMC material revealed that the first cycle irreversible capacity is the cause of slow lithium diffusion kinetics. In full-cells, however, this "lost" lithium ions can be used to build up the SEI of the graphite electrode during the initial formation cycle. A new systematic approach to correlate the lithium content in NMC with its lattice parameters (c, a) allows a convenient quantification of the loss of active lithium in aged cells by determining the c/a ratio of harvested NMC cathodes in the discharged state using ex situ XRD. Besides loss of active lithium, transition metal dissolution/deposition on graphite and growth of cell impedance strongly effect cell aging, especially at elevated temperatures and high upper cutoff potentials. Besides their current use in portable power electronics, lithium ion batteries have recently been used for battery electric vehicles (BEV) and are envisioned for large-scale energy storage. For the latter applications, life times of >10 years are required so that it is essential to understand and quantify the mechanisms that contribute to battery failure. Among the commercially available lithium-ion battery chemistries, 1,2 the graphite/LiNi 1/3 Mn 1/3 Co 1/3 O 2 (NMC) system is one of the materials currently envisioned for automotive applications. 3 This cathode material demonstrates high capacity, good structural stability due to its small volume changes (<2%) during Li insertion and extraction, and high thermal stability in the charged state. [4][5][6] In addition, this material could theoretically be operated with high charge cutoff potentials up to 5.0 V, as its bulk structure is claimed to be stabilized by the presence of Mn 4+ , 7 even though other authors suggest that irreversible structural changes occur at these very high potentials and at high temperature.8 Due to its sloped potential profile, the capacity and also the average cell voltage increase with increasing charging potential. 7,9 Despite the improved safety and cycling performance of NMC material, operating NMC based cells (full-cells or half-cells) at elevated temperatures or at high charge potential leads to poor cycle life. [10][11][12][13] During cycling of graphite/NMC full-cells, transition metal dissolution from the NMC material is found to be a crucial factor controlling capacity fade. 11,12 In one of these studies, Zheng et al. demonstrated that upper cutoff potentials of >4.3 V lead to transition metal dissolution from NMC and thus compromise cycling performa...

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“…[12,16,17] One of the primary efforts on layered cathodes is further unlocking its capacity potential by narrowing the gap between the practical capacity and theoretical capacity. [26][27][28] The detrimental effects of cracking include fracture caused disintegration, [28] which leads to poor electronic conduction [29,30] and loss of active materials, and new surfaces exposure to electrolyte which results in cathode surface degradation [31][32][33] and electrolyte consumption. [18][19][20] The surface/interface degradations are attributed to the chemical reactions between cathode and electrolyte, which leads to cathode surface phase transition, [21,22] active material dissolution, [23] passivation layer formation, [24] electrolyte consumption, [25] and so on.…”

mentioning

confidence: 99%

Dopant Segregation Boosting High‐Voltage Cyclability of Layered Cathode for Sodium Ion Batteries

et al. 2019

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PIBs). [7,8] Either in the form of O3 structure, P2 structure or other else structures, their common similarity is the layer by layer stacking sequence of transition metal ions, oxygen ions, and alkaline ions. [9,10] Such a layered structure not only enables high-specific capacity but also favors the fast migration of alkaline ions due to the unique 2D diffusion pathway. Thus, layer structured LiCoO 2 , ternary NMC (LiNi x Mn y Co z O 2 , x + y + z = 1), and NCA (LiNi 0.85 Co 0.1 Al 0.05 O 2 ) have achieved great commercial success as high-performance cathode materials for LIBs. [11][12][13] Other layered cathode materials, such as Ni-rich NMC for LIBs [14,15] and Na-NMC layered cathodes for SIBs, are gaining increasing attentions. [12,16,17] One of the primary efforts on layered cathodes is further unlocking its capacity potential by narrowing the gap between the practical capacity and theoretical capacity. However, increasing the utilization of alkaline ions, usually by elevating the high-charge cutoff voltage, results in structural instability of the layered cathodes, due to aggravated surface/ interface chemical degradations and bulk degradations. [18][19][20] The surface/interface degradations are attributed to the chemical reactions between cathode and electrolyte, which leads to cathode surface phase transition, [21,22] active material dissolution, [23] passivation layer formation, [24] electrolyte consumption, [25] and so on. For bulk degradations, irreversible bulk phase transition and cracking are the two main failure mechanisms. At high state of charge, phase transition not only destructs the active layered structure but also introduces substantial volume changes causing mechanical failures. A direct correlation between phase transition and cracking has been established in the P2 layered cathode for SIBs. [26] Cleavage along layered planes leads to the typical intragranular cracking for many layered cathodes, which has been frequently observed after high-voltage cycling. [26][27][28] The detrimental effects of cracking include fracture caused disintegration, [28] which leads to poor electronic conduction [29,30] and loss of active materials, and new surfaces exposure to electrolyte which results in cathode surface degradation [31][32][33] and electrolyte consumption. In addition, high density of intragranular cracks also plagues battery thermal stability and safety. [27] Doping electrochemically inactive elements has been verified as an effective method to improve the electrochemical performance of layered cathodes. [34,35] Dopants can play multiroles in engineering bulk material, such as eliminating unwanted As a widely used approach to modify a material's bulk properties, doping can effectively improve electrochemical properties and structural stability of various cathodes for rechargeable batteries, which usually empirically favors a uniform distribution of dopants. It is reported that dopant aggregation effectively boosts the cyclability of a Mg-doped P2-type layered cathode (Na 0.67 Ni 0.33 Mn 0.6...

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Effects of Dissolved Transition Metals on the Electrochemical Performance and SEI Growth in Lithium-Ion Batteries

Cited by 164 publications

References 51 publications

Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

Aging Analysis of Graphite/LiNi_1/3Mn_1/3Co_1/3O₂Cells Using XRD, PGAA, and AC Impedance

Dopant Segregation Boosting High‐Voltage Cyclability of Layered Cathode for Sodium Ion Batteries

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Effects of Dissolved Transition Metals on the Electrochemical Performance and SEI Growth in Lithium-Ion Batteries

Cited by 164 publications

References 51 publications

Temperature Dependence of Electrochemical Degradation in LiNi1/3Mn1/3Co1/3O2/Li4Ti5O12 Cells

Temperature Dependence of Electrochemical Degradation in LiNi1/3Mn1/3Co1/3O2/Li4Ti5O12 Cells

Aging Analysis of Graphite/LiNi1/3Mn1/3Co1/3O2Cells Using XRD, PGAA, and AC Impedance

Dopant Segregation Boosting High‐Voltage Cyclability of Layered Cathode for Sodium Ion Batteries

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Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

Temperature Dependence of Electrochemical Degradation in LiNi_1/3Mn_1/3Co_1/3O₂/Li₄Ti₅O₁₂ Cells

Aging Analysis of Graphite/LiNi_1/3Mn_1/3Co_1/3O₂Cells Using XRD, PGAA, and AC Impedance