Fading Mechanisms and Voltage Hysteresis in FeF 2 –NiF 2 Solid Solution Cathodes for Lithium and Lithium‐Ion Batteries

Hwang

Advanced Energy Materials

et al. 2020

110

Ni‐rich cathodes are considered feasible candidates for high‐energy‐density Li‐ion batteries (LIBs). However, the structural degradation of Ni‐rich cathodes on the micro‐ and nanoscale leads to severe capacity fading, thereby impeding their practical use in LIBs. Here, it is reported that 3‐(trimethylsilyl)‐2‐oxazolidinone (TMS‐ON) as a multifunctional additive promotes the dissociation of LiPF6, prevents the hydrolysis of ion‐paired LiPF6 (which produces undesired acidic compounds including HF), and scavenges HF in the electrolyte. Further, the presence of 0.5 wt% TMS‐ON helps maintain a stable solid–electrolyte interphase (SEI) at Ni‐rich LiNi0.7Co0.15Mn0.15O2 (NCM) cathodes, thus mitigating the irreversible phase transformation from layered to rock‐salt structures and enabling the long‐term stability of the SEI at the graphite anode with low interfacial resistance. Notably, NCM/graphite full cells with TMS‐ON, which exhibit an excellent discharge capacity retention of 80.4%, deliver a discharge capacity of 154.7 mAh g−1 after 400 cycles at 45 °C.

Section: Resultsmentioning

confidence: 99%

Cyclic Aminosilane‐Based Additive Ensuring Stable Electrode–Electrolyte Interfaces in Li‐Ion Batteries

Hwang

Advanced Energy Materials

et al. 2020

110

“…Thus, while the immediate local environment of cations (Li + or Na + ) still maintains the solvation structure of super-concentrated electrolytes, which is often responsible for the interphasial chemistries at electrode surfaces, the bulk properties (ion transport, viscosity, or wettability toward the electrodes and separators) were mainly defined by the average composition of the bulk electrolyte that still bear the nature of diluted regime. The simultaneous stabilization of the lithium metal and the high capacity and high voltage cathodes might have benefited from the highly fluorinated CEI formed by the partially fluorinated non-solvent and the defluorination of both LiFSI and LiPF 6, [39][40][41] while most of the ''oxidatively weak'' but highly Li + -solvating solvents were kept away due to the coulombic repulsion at the cathode surface. Because the strong salt aggregation is preserved locally in the electrolyte as a non-coordinated diluent is added, the preferential salt reduction that requires such aggregation is also preserved in the diluted regime.…”

Section: State Of the Art: Super-concentration And Its Derivativesmentioning

confidence: 99%

Uncharted Waters: Super-Concentrated Electrolytes

Borodin

Self

Persson

et al. 2020

Joule

Self Cite

382

373

As a legacy left behind by classical analytical electrochemistry in pursuit of ideal electrodics, and classical physical electrochemistry in pursuit of the most conductive ionics, the study of non-aqueous electrolytes has been historically confined within a narrow concentration regime around 1 molarity (M). This confinement was breached in recent years when unusual properties were found to arise from the excessive salt presence, which often bring benefits to electrochemical, thermal, transport, interfacial, and interphasial properties that are of significant interest to the electrochemical energy storage community. This article provides an overview on this newly discovered and under-explored realm, with emphasis placed on their applications in rechargeable batteries.

“…However, most of the previously reported metal fluoride particles did not yield uniform particles with a mean size of less than 100 nm and with controlled morphology . Hence, rate capability and cycle life were limited (only 100 cycles achievable in total, small active mass loading of ≈1.0 mg cm −2 or no indication of mass loadings) and these reports were far‐off from the standard of a practical application.…”

mentioning

confidence: 95%

“…However, composite design for performance enhancement focused mainly on S‐based rather than on metal fluoride cathodes. At present, metal fluoride materials such as FeF 3 , FeF 2 , CuF 2 , and CoF 2 are facing severe limitations in terms of low reversibility, large voltage hysteresis, rather poor rate capability, detrimental active material dissolution, and poor cycle life . To mitigate these issues, ball milling, particle designs, doping chemistry, and electrolyte modifications have been reported with the target of improving transport and reaction kinetics, stabilizing reaction interface, and suppressing active material dissolution and the related shuttle effects .…”

mentioning

confidence: 99%

3D Honeycomb Architecture Enables a High‐Rate and Long‐Life Iron (III) Fluoride–Lithium Battery

Šrot

Chen

et al. 2019

Advanced Materials

Lithium-ion (Li-ion) batteries as one of the most popular energy storage systems have been widely used in laptops, mobile phones, cameras, electric tools, and cars. However, the commercial Li-ion batteries employing Ni-and Co-based intercalation-type cathodes with limited capacities and energy densities cannot meet the rapidly rising market demands in Metal fluoride-lithium batteries with potentially high energy densities, even higher than lithium-sulfur batteries, are viewed as very promising candidates for next-generation lightweight and low-cost rechargeable batteries. However, so far, metal fluoride cathodes have suffered from poor electronic conductivity, sluggish reaction kinetics and side reactions causing high voltage hysteresis, poor rate capability, and rapid capacity degradation upon cycling. Herein, it is reported that an FeF 3 @C composite having a 3D honeycomb architecture synthesized by a simple method may overcome these issues. The FeF 3 nanoparticles (10-50 nm) are uniformly embedded in the 3D honeycomb carbon framework where the honeycomb walls and hexagonal-like channels provide sufficient pathways for the fast electron and Li-ion diffusion, respectively. As a result, the as-produced 3D honeycomb FeF 3 @C composite cathodes even with high areal FeF 3 loadings of 2.2 and 5.3 mg cm −2 offer unprecedented rate capability up to 100 C and remarkable cycle stability within 1000 cycles, displaying capacity retentions of 95%-100% within 200 cycles at various C rates, and ≈85% at 2C within 1000 cycles. The reported results demonstrate that the 3D honeycomb architecture is a powerful composite design for conversion-type metal fluorides to achieve excellent electrochemical performance in metal fluoride-lithium batteries.