Lithium reactivity with electrolytes leads to their continuous consumption and dendrite growth, which constitute major obstacles to harnessing the tremendous energy of lithium-metal anode in a reversible manner. Considerable attention has been focused on inhibiting dendrite via interface and electrolyte engineering, while admitting electrolyte-lithium metal reactivity as a thermodynamic inevitability. Here, we report the effective suppression of such reactivity through a nano-porous separator. Calculation assisted by diversified characterizations reveals that the separator partially desolvates Li+ in confinement created by its uniform nanopores, and deactivates solvents for electrochemical reduction before Li0-deposition occurs. The consequence of such deactivation is realizing dendrite-free lithium-metal electrode, which even retaining its metallic lustre after long-term cycling in both Li-symmetric cell and high-voltage Li-metal battery with LiNi0.6Mn0.2Co0.2O2 as cathode. The discovery that a nano-structured separator alters both bulk and interfacial behaviors of electrolytes points us toward a new direction to harness lithium-metal as the most promising anode.
Oxygen redox at high-voltage has emerged as a transformative paradigm for high-energy battery cathodes by offering extra capacity beyond conventional transition-metal redox. However, it suffers from voltage hysteresis, voltage fade, and capacity drop upon cycling. Here, we show that, by eliminating the domain boundaries in the often-considered single-crystalline battery particles, layered oxide cathodes demonstrate exceptional capacity and voltage stability during high-voltage operation. Our combined experimental and theory studies for the first time reveal that the elimination of domain boundaries could enhance the reversible lattice oxygen redox while inhibiting the irreversible oxygen release, leading to significantly suppressed structural degradation and improved mechanical integrity during battery cycling and abuse heating. The robust oxygen redox enabled through domain boundary control provides practical opportunities towards high-energy, long-cycling, and safe batteries. MainHigh-energy batteries rely on high-capacity and high-voltage operation of the cathodes.Fundamentally, the capacity of a transition metal oxide-based cathode is determined by the amount of active Li, while the voltage is defined by the redox reactions affected by structural configurations 1 . This has led to two associated trends in recent cathode development: Li-excess compounds due to the large amount of Li (capacity) and oxygen redox (OR) at high-voltage 2-6 .However, intensive studies have shown that OR activities can trigger detrimental structural effects such as oxygen release, surface reactions, and phase transition, leading to severe voltage hysteresis, voltage fade, and poor capacity stability 3,5 . Despite extensive mechanistic understanding 3,5 and material optimization such as structural control [7][8][9] , chemical composition manipulation 10 , and cationic/anionic doping [11][12][13] , the fundamental origin of the OR instability remains under active debate, and the practical control of high-voltage operation involving OR remains a formidable challenge. The key relies on a strategy that enhances the reversible OR in the lattice, while suppressing or even eliminating other detrimental oxygen activities.Theoretical studies suggest that the surface could favour the migration of oxygen ions and promote the formation of oxygen vacancies due to the open atomic structure [14][15][16] . Therefore, surface-initiated irreversible oxygen loss and the associated structural transformation have long been considered as the root cause of the capacity decay and voltage fade of Li-excess layered cathodes when activating the OR process [16][17][18] . However, surface coatings to mitigate the oxygen loss have proven insufficient to achieve a fully reversible OR 5,18,19 .Grain boundaries (GBs), the surface that separates individual grains from each other, play a vital role in materials' properties. In layered oxide cathodes, the GBs have been predominantly referred to the boundaries between primary particles of polycrystalline cathodes, while ...
High-voltage operation is essential for the energy and power densities of battery cathode materials, but its stabilization remains a universal challenge. To date, the degradation origin has been mostly attributed to cycling-initiated structural deformation while the effect of native crystallographic defects induced during the sophisticated synthesis process has been significantly overlooked. Here, using in situ synchrotron X-ray probes and advanced transmission electron microscopy to probe the solid-state synthesis and charge/discharge process of sodium layered oxide cathodes, we reveal that quenching-induced native lattice strain plays an overwhelming role in the catastrophic capacity degradation of sodium layered cathodes, which runs counter to conventional perception—phase transition and cathode interfacial reactions. We observe that the spontaneous relaxation of native lattice strain is responsible for the structural earthquake (e.g., dislocation, stacking faults and fragmentation) of sodium layered cathodes during cycling, which is unexpectedly not regulated by the voltage window but is strongly coupled with charge/discharge temperature and rate. Our findings resolve the controversial understanding on the degradation origin of cathode materials and highlight the importance of eliminating intrinsic crystallographic defects to guarantee superior cycling stability at high voltages.
storage systems (ESSs) to mitigate the intrinsically intermittent nature of renewable energy sources. [1] Lithium-ion batteries (LIBs), one of the most mature electrochemical ESSs, undergo rapid development and have widespread applications in portable devices, (hybrid) electric vehicles, as well as grid storage. [2] With the ever-growing demands for energy density, various novel materials (e.g., silicon), as well as electrode technologies (e.g., ultra-thick electrode), have been proposed for high-capacity applications as shown in Figure 1a. [3] There is a consistent trend/ need to evaluate the electrochemical behaviors of the high-capacity electrode using an increasing current density to match state-of-the-art lithium-ion technologies, e.g. the initial testing current for mechanism analysis of graphite in the 1990s was 0.2 mA cm −2 ; [4] while it goes to 10 mA cm −2 for performance competition of modern electrodes, equivalent to a 50-fold increase. [5] Along with the progress of electrode materials and technologies, less progress was made to parallelly upgrade the electrochemical evaluation methods. In 1980s, the classic three-electrode Pyrex glass cell with Li metal as the reference electrode was replaced by the two-electrode coin cell configuration with reduced distance between electrodes and amount of electrolyte to eliminate the non-negligible parasitic current and undesirable ohmic resistance. [6] Since then, the two-electrode coin-cell-type half-cells with Li metal as counter and reference electrodes have been the Developing high-capacity electrodes requires the evaluation of electrochemical behaviors with an increasing current density. Currently, the current density for evaluation of high-capacity electrodes has reached a new stage where the polarization at the lithium counter electrode has become a technical barrier for the accurate evaluation of battery electrodes, resulting in severe performance and mechanism mischaracterizations. Here, the accurate electrochemical behavior for high-capacity electrodes via a singlechannel three-electrode vehicle is decoupled, by which the impact of lithium counter electrode is minimized. The testing high-capacity graphite electrode is capable of delivering an excellent rate capability with 81.7% capacity retention at 0.3 C, as well as stable cycling performance retaining 97.5% practical reversible capacity after 225 cycles, much higher than the graphite electrode tested with traditional half-cell testing vehicle but in close agreement with the results obtained from a well-matched full cell, reflecting accurate electrochemical performance evaluations of high-capacity electrodes. Moreover, detailed electrochemical mechanisms of impedance and diffusion properties for working electrodes are also successfully decoupled individually. This work uncovers the mismatch between traditional evaluation configuration and increasing testing current density and provides a guideline for accurate electrochemical evaluation for ever-increasing highcapacity electrodes, which is of great s...
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