Herein, a new fluorine-containing sulfone-based electrolyte system for stabilizing lithium metal anode was developed by utilizing lithium bis (fluorosulfonyl)imide (LiFSI) as
Herein, we provide an overview of the diverse roles and significant impacts of fluorine-containing materials in enhancing the performance, efficiency, and safety of these
Given the pivotal role of cathodes in determining battery cost and performance, numerous endeavors have been devoted to developing advanced sodium-storage cathode
F-HV can also generate fluorine-containing carbon layer with high specific surface area to isolate oxygen and fuel, thus preventing further combustion. F-HV is expected to
Herein, a new fluorine-containing sulfone-based electrolyte is proposed for lithium metal batteries. Benefiting from the synergistic effect of lithium bis (fluorosulfonyl)imide (LiFSI) and
This Review explores the design and utilization of fluorine-containing species in advanced batteries, focusing on the relationship between the chemical structure of the species
Furthermore, the necessity of disposal and recycling fluorine-containing energy storage devices also presents related ecological and health-related concerns. [3] Considerable
This work provides guidance for the development of fluorine-containing sulfone-based electrolyte to achieve high energy density lithium metal batteries in the future.
With the popularity and widespread applications of electronics, higher demands are being placed on the performance of battery materials. Due to the large difference in
These simulated data preliminarily denote that such fluorine-containing porous materials perform poorly in energy gas storage. On the other hand, the heat of adsorption is
Fluorine additives and co-solvents enable increased energy per mass of battery whilst ensuring safety. The unique properties of fluorine-containing materials make them uniquely suited for
Rechargeable lithium metal batteries (LMBs) with high energy density are increasingly pivotal for global sustainable development. However, the uncontrolled growth of
Recent results on the electrochemical properties of surface-fluorinated graphites and fluoroesters and fluoroethers as rechargeable lithium battery materials are summarized. Surface
Fluorine-Containing Phase-Separated Polymer Electrolytes Enabling High-Energy Solid-State Lithium Metal Batteries Advanced Functional Materials ( IF 19 ) Pub Date : 2024-01-10, DOI:
The strategy of introducing vacancies has been employed to modify functional materials in various types of energy storage systems, and as can be seen from Table 1,
A new fluorine-containing sulfone-based electrolyte for advanced performance lithium metal batteries Lithium dendrite growth greatly limits the application of lithium metal batteries.
Energy storage and conversion are vital for addressing global energy challenges, particularly the demand for clean and sustainable energy. Functional organic materials are gaining interest as
Sustainable energy storage materials can address environmental, safety, security, and ethical issues associated with conventional battery platforms.
This review systematically discusses the advances in these fluorinated electrode materials. First, comprehensive insights into fluorinated
In recent years, renewable energy sources, which aim to replace rapidly depleting fossil fuels, face challenges due to limited energy storage and conversion
Fluorination is one of the most efficient and universal strategies to increase the hydrophobicity of materials and consequently their water
Li metal is an indispensable anode material for realizing high-energy rechargeable batteries owing to its high capacity and low reduction potential [1], [2], [3].
Solid-state lithium (Li) metal batteries (LMBs) have been developed as a promising replacement for conventional Li-ion batteries due to
Here, authors designed fluorine-doped micropore-covered mesoporous carbon fibers as current collectors for anode-free Na metal batteries with improved cycle life.
Developing energy storage technologies using low-cost, earth abundant materials are key to successful energy transition in the transportation and electric power generation
The fluorine-containing covalent organic frameworks (fCOFs) have been developed for special applications by virtue of special physical and chemical
High-capacity and high-voltage fluorinated electrode materials have attracted great interest for next-generation high-energy batteries, which is associated with the high
Molecules featuring fluorine-containing functional groups exhibit outstanding properties with high density, low sensitivity, excellent thermal
Fluorine-containing hydrogen bonds induce uniform distribution of charges and accelerating the ions migration at the electrolyte/electrode interface. Benefiting from the improvements in
Fluorinated materials are carbon-based polymers, liquids, or gases that contain large amounts of chemically bonded fluorine, exhibiting unique properties such as chemical inertness, extreme
Fluorine-containing hydrogen bonds induce uniform distribution of charges and accelerating the ions migration at the electrolyte/electrode interface. Benefiting from the improvements in
Establishing a harmonious equilibrium between high energy storage, minimal energy loss, and exceptional processability presents a formidable challenge within the realm of dielectric
In addition, the fluorine-containing groups are conducive to constructing PI-based aerogels with hydrophobicity, flame retardancy, and intrinsic UV resistance, exhibiting potential
While fluorides have been recently introduced in energy conversion applications such as electrolytes for fuel cells, transparent electrodes for solar cells, and electrodes for aqueous batteries, the application of fluorine based materials has manifested itself to a great extent in high energy lithium nonaqueous batteries.
Fluorine based materials have been gradually entering a prominent place in energy storage and conversion, resulting in materials of great performance and stability.
Fluorinated carbon materials (CF x) have been widely used as cathode materials in primary batteries and simultaneously been applied to modify electrode materials in secondary rechargeable lithium-ion batteries (LIBs) owing to the unique discharge product of LiF and carbon.
Incorporating fluorine into battery components can improve the energy density, safety and cycling stability of rechargeable batteries.
In the process of energy storage, metal fluorides exhibit high operating voltages and large storage capacities, making them promising electrode materials for future high-energy-density applications.
The incorporation of fluorine-containing functional moieties is critical for the development of novel high energy density materials, and is rapidly being adopted in the design of energetic materials. Recent Advances in Chemistry of Nitrogen-Rich Energetic Polymers and Plasticizers in Nitrogen-Rich Energetic Materials (Ed.:
