Tuning the Li/Ni Disorder of the NMC811 Cathode by Thermally Driven Competition between Lattice Ordering and Structure Decomposition

Wang, Ting; Ren, Kun; Xiao, Wei; Dong, Wenhao; Qiao, Huali; Duan, Anran; Pan, Haitao; Yang, Yang; Wang, Hailong

doi:10.1021/acs.jpcc.0c00720

Cited by 64 publications

(43 citation statements)

References 57 publications

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“…The high Ni and low Co can lead to a high capacity and low price, meanwhile a poor cycling stability and high safety hazard. Electrolyte modification, 31–33 interfacial design, 34–36 postsynthesis annealing, 37 and morphology regulation, 38 can efficiently relieve these issues. LFP: Reported firstly in 1997 by Goodenough et al., LFP has become an important electrode material (Figure 3B), 39 which has excellent long‐term cycling ability, thermal stability, environmental friendliness, and low cost. Compared with LCO and NMC, the theoretical capacity of LFP is relatively low (170 mAh/g at room temperature), which limits the practical application of LFP, especially in EVs 40 .…”

Section: Low‐cobalt Cathodementioning

confidence: 99%

“…The high Ni and low Co can lead to a high capacity and low price, meanwhile a poor cycling stability and high safety hazard. Electrolyte modification, [31][32][33] interfacial design, [34][35][36] postsynthesis annealing, 37 and morphology regulation, 38 can efficiently relieve these issues. 3B), 39 which has excellent long-term cycling ability, thermal stability, environmental friendliness, and low cost.…”

Section: Low-cobalt Cathodementioning

confidence: 99%

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A perspective on sustainable energy materials for lithium batteries

Cheng

Lin

Yuan

et al. 2021

SusMat

236

147

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Lithium ion battery has achieved great success in portable electronics and even recently electronic vehicles since its commercialization in 1990s. However, lithium-ion batteries are confronted with several issues in terms of the sustainable development such as the high price of raw materials and electronic products, the emerging safety accidents, etc. The recent progresses are herein emphasized on lithium batteries for energy storage to clearly understand the sustainable energy chemistry and emerging energy materials. The Perspective presents novel lithium-ion batteries developed with the aims of enhancing the electrochemical performance and sustainability of energy storage systems. First, revolutionary material chemistries, including novel low-cobalt cathode, organic electrode, and aqueous electrolyte, are discussed. Then, the characteristics of safety performance are analyzed and strategies to enhance safety are subsequently evaluated. Battery recycling is considered as the key factor for a sustainable society and related technologies are present as well. Finally, conclusion and outlook are drawn to shed lights on the further development of sustainable lithium-ion batteries.

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Section: Low‐cobalt Cathodementioning

confidence: 99%

Section: Low-cobalt Cathodementioning

confidence: 99%

A perspective on sustainable energy materials for lithium batteries

Cheng

Lin

Yuan

et al. 2021

SusMat

236

147

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“…Lithium nickel manganese cobalt oxide (NMC) cathodes have been critical pillars of advanced lithium ion batteries at current state (Chen et al, 2019;Xu et al, 2019;Zhou et al, 2019;Kim et al, 2020;Li et al, 2020;Wang et al, 2020b;Wu et al, 2020;Zhang, 2020;Zheng et al, 2020). The particle's crystallinity and morphology can put significant influences on the energy density, cycling stability, and rate capability of the NMC cathodes in practical applications (Liu et al, 2018;Fan et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“…The polycrystalline nature of the secondary particles presents many issues, including (1) low tap density (<3.3 g cm −3 ) compared with the single-crystalline LiCoO 2 cathode (3.9 g cm −3 ), which leads to an inadequate volumetric energy density (Kim et al, 2018 ), (2) the formation of microcracks inside the secondary particle incurred by the anisotropic lattice expansion and shrink during charging/discharging, which gradually deteriorates the cycling stability (Kim et al, 2018 ; Liu et al, 2018 ), and (3) the porous structure of the secondary particle prevents homogeneous carbon coating on each primary particle, which results in unsatisfactory electrical contact between the active material and the current collector (Kimijima et al, 2016b ). In the recent decade, the chasing of larger gravimetric capacity has pushed the nickel content of the NMC to over 60%; as a tradeoff larger gravimetric capacity, these nickel-rich NMC cathodes are suffering more serious issues caused by the polycrystalline secondary particles (Dixit et al, 2017 ; Kim et al, 2018 ; Lee et al, 2018 ; Liang et al, 2018 ; Ryu et al, 2018 ; Fan et al, 2020 ; Wang et al, 2020b ). The mandatory increase of the tap density to over 3.3 g cm −3 generally leads to rapid capacity fading since the polycrystalline secondary particles would crack and collapse during high-pressure electrode pressing (Kim et al, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Synthesis and Manipulation of Single-Crystalline Lithium Nickel Manganese Cobalt Oxide Cathodes: A Review of Growth Mechanism

et al. 2020

Self Cite

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Lithium nickel manganese cobalt oxide (NMC) cathodes are of great importance for the development of lithium ion batteries with high energy density. Currently, most commercially available NMC products are polycrystalline secondary particles, which are aggregated by anisotropic primary particles. Although the polycrystalline NMC particles have demonstrated large gravimetric capacity and good rate capabilities, the volumetric energy density, cycling stability as well as production adaptability are not satisfactory. Well-dispersed single-crystalline NMC is therefore proposed to be an alternative solution for further development of high-energy-density batteries. Various techniques have been explored to synthesize the single-crystalline NMC product, but the fundamental mechanisms behind these techniques are still fragmented and incoherent. In this manuscript, we start a journey from the fundamental crystal growth theory, compare the crystal growth of NMC among different techniques, and disclose the key factors governing the growth of single-crystalline NMC. We expect that the more generalized growth mechanism drawn from invaluable previous works could enhance the rational design and the synthesis of cathode materials with superior energy density.

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“…Representative approaches include lattice doping, [14,15,16] surface processing/modification and tuning of material compositions. [17,18,19,20] Other synthetic conditions, such as calcination temperature, [22,23] calcination atmosphere [20] or are important in determining structural properties (incl. Li/Ni cation mixing) and thus influencing the electrochemical performance of high Ni cathode.…”

Section: Introductionmentioning

confidence: 99%

Gas impurity in calcination atmosphere governing electrochemical properties of LiNi0.8Mn0.1Co0.1O2 cathode material for lithium ion batteries

Kim

Wang

Verthamon

et al. 2022

Preprint

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In this work, we investigated the influence of gas impurity in oxygen as calcination gas on the electrochemical properties of high Ni LiNi0.8Mn0.1Co0.1O2 (NMC811) cathode materials. Among investigated gas compositions, the oxygen mixed with a small amount of argon (96% O2, 4% Ar) shows the same level of Li/Ni cation mixing as 100% O2 sample, with not only a very stable discharge capacity retention (89% at 200 cycles) but also higher C-rate capability (67% at 20C) compared to other samples. Despite well suppressed Li/Ni cation mixing, 100% O2 sample suffers from an over-oxidation of Ni and Co of the surface, leading to an increase of surface resistance, as a consequence, a fast capacity fade over cycling with lower C-rate capability compared to the material calcined under 96% O2/4% Ar. This result demonstrates that calcination gas composition plays a key role in determining the electrochemical properties of high Ni cathode materials, not only in terms of Li/Ni cation mixing in the bulk structure, but also the oxidation properties of Ni, Co at the surface.

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Tuning the Li/Ni Disorder of the NMC811 Cathode by Thermally Driven Competition between Lattice Ordering and Structure Decomposition

Cited by 64 publications

References 57 publications

A perspective on sustainable energy materials for lithium batteries

A perspective on sustainable energy materials for lithium batteries

Synthesis and Manipulation of Single-Crystalline Lithium Nickel Manganese Cobalt Oxide Cathodes: A Review of Growth Mechanism

Gas impurity in calcination atmosphere governing electrochemical properties of LiNi0.8Mn0.1Co0.1O2 cathode material for lithium ion batteries

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