Single-particle measurements of electrochemical kinetics in NMC and NCA cathodes for Li-ion batteries

Tsai, Pei-Hsun; Wen, Bohua; Wolfman, Mark; Choe, Min-Ju; Pan, Menghsuan Sam; Su, Liang; Thornton, Katsuyo; Cabana, Jordi; Chiang, Yet‐Ming

doi:10.1039/c8ee00001h

Cited by 258 publications

(259 citation statements)

References 47 publications

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“…As shown in Supplementary Fig. 2a, the three-dimensional (3D) rendering and the virtual xy-slice through the center of the particle highlight the mesoscale morphological defects that are formed upon electrochemical cycling prior to any thermal treatments [21][22][23][24][25] . We present the morphological comparison between the initial state at room temperature and the state after the particle was exposed to the mildly elevated temperature at ~100 o C for ~5 hours.…”

Section: Resultsmentioning

confidence: 99%

Surface-to-Bulk Redox Coupling through Thermally Driven Li Redistribution in Li- and Mn-Rich Layered Cathode Materials

Lee

Wang

et al. 2019

J. Am. Chem. Soc.

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Li-and Mn-rich (LMR) layered cathode materials have demonstrated impressive capacity and specific energy density thanks to their intertwined redox centers including transition metal cations and oxygen anions. Although tremendous efforts have been devoted to the investigation of the electrochemically-driven redox evolution in LMR cathode at ambient temperature, their behavior under a mildly elevated temperature (up to ~100 o C), with or without electrochemical driving force, remains largely unexplored. Here we show a systematic study of the thermallydriven surface-to-bulk redox coupling effect in charged Li 1.2 Ni 0.15 Co 0.1 Mn 0.55 O 2. We observed a charge transfer between the bulk oxygen anions and the surface transition metal cations, suggesting that the thermally-enhanced Li + mobility in the hosting LMR lattice could lead to significant redistribution of Li ions. Our results highlight the non-equilibrium state and dynamic nature of LMR material at deeply delithiated state and its relaxation process in response to a mild temperature perturbation.

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Section: Resultsmentioning

confidence: 99%

Surface-to-Bulk Redox Coupling through Thermally Driven Li Redistribution in Li- and Mn-Rich Layered Cathode Materials

Lee

Wang

et al. 2019

J. Am. Chem. Soc.

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“…b) Transmission X‐ray microscopy tomograms showing slices at their midpoints of individual particles of the NCM333 and NCA after charging at C/3 rate to 3.9, 4.1, and 4.5 V, respectively. Reproduced with permission . Copyright 2018, Royal Society of Chemistry.…”

Section: Origins Of Surface/interface Structure Degradationmentioning

confidence: 99%

Surface/Interface Structure Degradation of Ni‐Rich Layered Oxide Cathodes toward Lithium‐Ion Batteries: Fundamental Mechanisms and Remedying Strategies

Liang

Zhang

Zhao

et al. 2019

Adv Materials Inter

149

111

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Nickel‐rich layered transition‐metal oxides with high‐capacity and high‐power capabilities are established as the principal cathode candidates for next‐generation lithium‐ion batteries. However, several intractable issues such as the poor thermal stability and rapid capacity fade as well as the air‐sensitivity particularly for the Ni content over 80% have seriously restricted their broadly practical applications. The properties and nature of the stable surface/interface, where the Li+ shuttles back and forth between the cathode and electrolyte, play a significant role in their ultimate lithium‐storage performance and industrial processability. Thus, tremendous efforts are made to in‐depth understanding of the essential origins of surface/interface structure degradation and efficient surface modification methodologies are intensively explored. The purpose of the contribution is first to provide a comprehensive review of the up‐to‐date mechanisms proposed to rationally elucidate the surface/interface behaviors, and then, focus on recent developed strategies to optimize the surface/interface structure and chemistry including synthetic condition regulation, surface doping, surface coating, dual doping‐coating modification, and concentration‐gradient structure as well as electrolyte additives. Finally, the perspective on future research trends and feasible approaches toward advanced Ni‐rich cathodes with stable surface/interface is presented briefly.

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“…Very recently, it has been shown that by understanding the functional form of the reaction rate expressions, one is able to control, and consequently engineer, the physics of interfaces where reactions take place [26]. Representative examples are the lithiation of LFP and LiNi 1/3 Mn 1/3 Co 1/3 O 2 [149,150] particles, as well as the operation of Li-air batteries, where the thermodynamic stability of the system is controlled by varying the applied current [13,95,102,151,152]. In terms of CIET, by understanding the concentration dependencies of both the reorganization energy and the density of states of the electron donor, we will be able to control interface structure by inducing or suppressing phase separation/island formation.…”

Section: Discussionmentioning

confidence: 99%

Theory of Coupled Ion-Electron Transfer Kinetics in Ion Intercalation Materials

et al. 2020

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The microscopic theory of chemical reactions is based on transition state theory, where atoms or ions transfer classically over an energy barrier, as electrons maintain their ground state. Electron transfer is fundamentally different and occurs by tunneling in response to solvent fluctuations. Here, we develop the theory of coupled ion-electron transfer, in which ions and solvent molecules fluctuate cooperatively to facilitate electron transfer. We derive a general formula of the reaction rate that depends on the overpotential, solvent properties, the electronic structure of the electron donor/acceptor, and the excess chemical potential of ions in the transition state. For Faradaic reactions, the theory predicts curved Tafel plots with a concentration-dependent reaction-limited current. For moderate overpotentials, our formula reduces to the Butler-Volmer equation and explains its relevance, not only in the well-known limit of large electron-transfer (solvent reorganization) energy, but also in the opposite limit of large ion-transfer energy. The rate formula is applied to Li-ion batteries, where reduction of the electrode host material couples with ion insertion. In the case of lithium iron phosphate, the theory accurately predicts the concentration dependence of the exchange current measured by in operando X-Ray microscopy without any adjustable parameters. These results pave the way for interfacial engineering to enhance ion intercalation rates, not only for batteries, but also for ionic separations and neuromorphic computing.

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Single-particle measurements of electrochemical kinetics in NMC and NCA cathodes for Li-ion batteries

Cited by 258 publications

References 47 publications

Surface-to-Bulk Redox Coupling through Thermally Driven Li Redistribution in Li- and Mn-Rich Layered Cathode Materials

Surface-to-Bulk Redox Coupling through Thermally Driven Li Redistribution in Li- and Mn-Rich Layered Cathode Materials

Surface/Interface Structure Degradation of Ni‐Rich Layered Oxide Cathodes toward Lithium‐Ion Batteries: Fundamental Mechanisms and Remedying Strategies

Theory of Coupled Ion-Electron Transfer Kinetics in Ion Intercalation Materials

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