In this context, we discuss the microscopic kinetic processes, outline the challenges and requirements for low-temperature operation, highlight the materials and chemistry design strategies, and propose the future
In this article, we provide an overview of the low-temperature limiting mechanisms intrinsic to the lithium-ion battery chemistry, and then survey the field of next-generation battery chemistries
Recently, great efforts have been devoted to the expeditions on low-temperature LMBs, which promote the establishment of fundamental recognitions of low-temperature
In the last decade, the Li + solvation structure in electrolytes continues to gain attention, and an increasing number of research efforts are focused on understanding the impact of solvation structure on Li + transport and interphasial chemistry, aiming to improve battery performance by designing intermolecular interactions in the solvation structure [28, 29], which
Recently, great efforts have been devoted to the expeditions on low-temperature LMBs, which promote the establishment of fundamental recognitions of low-temperature battery chemistry, and proposal of various strategies to tame the low-temperature challenges.
Therefore, the rational formulation of electrolytes is significant for realizing superior low‐temperature performance and broadening application niches of LIBs. Herein, we first discuss the...
Among various rechargeable batteries, the lithium-ion battery (LIB) stands out due to its high energy density, long cycling life, in addition to other outstanding properties. However, the capacity of LIB drops dramatically at low temperatures (LTs) below 0 °C, thus restricting its applications as a reliable power source for electric vehicles in cold climates and
Citation: Wang, B.; Yan, M. Research on the Improvement of Lithium-Ion Battery Performance at Low Temperatures Based on Electromagnetic Induction Heating Technology. Energies 2023, 16, 7780. https
Here, a comprehensive research progress and in-depth understanding of the critical factors leading to the poor low-temperature performance of LIBs is provided; the distinctive challenges on the anodes, electrolytes, cathodes, and electrolyte–electrodes interphases are sorted out, with a special focus on Li-ion transport mechanism therein.
This article aims to review challenges and limitations of the battery chemistry in low-temperature environments, as well as the development of low-temperature LIBs from cell level to system level. This review introduces feasible solutions to accelarate low-temperature kinetics by increasing the inherent reactivity from cell design and improving
MIT engineers designed a battery made from inexpensive, abundant materials, that could provide low-cost backup storage for renewable energy sources. Less expensive than lithium-ion battery technology, the new architecture uses aluminum and sulfur as its two electrode materials with a molten salt electrolyte in between.
Therefore, the rational formulation of electrolytes is significant for realizing superior low‐temperature performance and broadening application niches of LIBs. Herein, we first discuss the...
Especially at low temperature, the increased viscosity of the electrolyte, reduced solubility of lithium salts, crystallization or solidification of the electrolyte, increased resistance to charge transfer due to interfacial by-products, and short-circuiting due to the growth of anode lithium dendrites all affect the performance and safety of LIBs.
Low-temperature electrolytes applied in lithium-ion batteries (LIBs) are systematically evaluated in this review, with a special focus on electrolyte formulation, electrolyte structure, electrolyte c...
Since the very initial research on low-temperature Li-ion batteries, Smart et al. have devoted considerable attention to solvent optimization, their main concept being to reduce the ratio of EC solvent [24, 26]. By boosting the ratio of low-melting-point linear carbonate ester solvents, poor low-temperature performance can be somewhat mitigated
Here, a comprehensive research progress and in-depth understanding of the critical factors leading to the poor low-temperature performance of LIBs is provided; the
The low temperature performance of rechargeable batteries, however, are far from satisfactory for practical applications. Serious problems generally occur, including decreasing reversible capacity and poor cycling performance. [] The degradation of the battery performance at low temperature could originate from the significant changes with temperature in electrolytes, interfaces, and
Continued research and development in battery technology will drive the growth and widespread adoption of electric vehicles, contributing to a more sustainable and clean transportati on future.
Low-temperature electrolytes applied in lithium-ion batteries (LIBs) are systematically evaluated in this review, with a special focus on electrolyte formulation, electrolyte structure, electrolyte c...
This article aims to review challenges and limitations of the battery chemistry in low-temperature environments, as well as the development of low-temperature LIBs from cell
In this mini-review discussing the limiting factors in the Li-ion diffusion process, we propose three basic requirements when formulating electrolytes for low-temperature Li-ion
Sodium-ion batteries (SIBs) have garnered significant interest due to their potential as viable alternatives to conventional lithium-ion batteries (LIBs), particularly in environments where low-temperature (LT) performance is crucial.
Sodium-ion batteries (SIBs) have garnered significant interest due to their potential as viable alternatives to conventional lithium-ion batteries (LIBs), particularly in environments where low-temperature (LT) performance
Especially at low temperature, the increased viscosity of the electrolyte, reduced solubility of lithium salts, crystallization or solidification of the electrolyte, increased resistance to charge transfer due to interfacial by
In this context, we discuss the microscopic kinetic processes, outline the challenges and requirements for low-temperature operation, highlight the materials and chemistry design strategies, and propose the future directions to enhance the performance at cold environments, especially from the perspective of solid electrolytes, interface, and ele...
He received his B.S. degree from the School of Chemical Engineering and Technology (2016), China University of Mining and Technology, and a Ph.D. degree from National Power Battery Innovation Centre at General Research Institute for Nonferrous Metals (2022). His main research work focuses on sodium-ion and Li-rich cathode materials, with a particular
In this mini-review discussing the limiting factors in the Li-ion diffusion process, we propose three basic requirements when formulating electrolytes for low-temperature Li-ion batteries: low melting point, poor Li + affinity, and a favorable SEI. Then, we briefly review emerging progress, including liquefied gas electrolytes, weakly solvating
In this article, we provide an overview of the low-temperature limiting mechanisms intrinsic to the lithium-ion battery chemistry, and then survey the field of next-generation battery chemistries that may potentially be better suited for performance-critical, low-temperature applications.
Especially at low temperature, the increased viscosity of the electrolyte, reduced solubility of lithium salts, crystallization or solidification of the electrolyte, increased resistance to charge transfer due to interfacial by-products, and short-circuiting due to the growth of anode lithium dendrites all affect the performance and safety of LIBs.
Although many efforts have been made in the research of low-temperature batteries, some studies are scattered and cannot provide systematic solutions. In the future study, high-throughput experiments can be used to screen materials and electrolytes suitable for low-temperature batteries.
At low temperatures, the critical factor that limits the electrochemical performances of batteries has been considered to be the sluggish kinetics of Li +. 23,25,26 Consequently, before seeking effective strategies to improve the low-temperature performances, it is necessary to understand the kinetic processes in ASSBs.
In general, a systematic review of low-temperature LIBs is conducted in order to provide references for future research. 1. Introduction Lithium-ion batteries (LIBs) have been the workhorse of power supplies for consumer products with the advantages of high energy density, high power density and long service life .
However, faced with diverse scenarios and harsh working conditions (e.g., low temperature), the successful operation of batteries suffers great challenges. At low temperature, the increased viscosity of electrolyte leads to the poor wetting of batteries and sluggish transportation of Li-ion (Li +) in bulk electrolyte.
As one of the fundamental components of a battery, the electrolyte greatly affects the low-temperature operation of LMBs. The electrolyte formulations have great influence on the ion conductivity, viscosity, interface features (e.g., compositions, structure and properties), solvation structure and de-solvation behaviors.
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