Lithium-ion batteries are the most ubiquitous energy storage devices in our everyday lives. However, their energy storage capacity fades over time due to chemical and structural changes in their components, via different degradation mechanisms. Understanding and mitigating these degradation mechanisms is key to reducing capacity fade, thereby enabling improvement in the performance and lifetime of Li-ion batteries, supporting the energy transition to renewables and electrification. In this endeavor, surface analysis techniques are commonly employed to characterize the chemistry and structure at reactive interfaces, where most changes are observed as batteries age. However, battery electrodes are complex systems containing unstable compounds...
Cell aging is a major issue in battery cells, as it affects the application capabilities. The mechan...
Understanding and improving the behavior of interfaces is essential to the development of safer and ...
Degradation mechanisms in 26 Ah commercial Li-ion battery cells comprising graphite as the negative ...
Lithium-ion batteries are the most ubiquitous energy storage devices in our everyday lives. However,...
Layered LiNi[subscript 0.8]Mn[subscript 0.1]Co[subscript 0.1]O[subscript 2](NMC811) is one of the hi...
Lithium- and manganese-rich layered-oxides (LMR-NMC) have potential application for electric vehicle...
The stability of electrode/electrolyte interfaces in Li-ion batteries is crucial to the performance,...
Lithium-ion technology is considered as outstanding candidate for implementation in high energy dens...
Energy storage technologies are crucial in the next green-energy transition. In particular, Li-ion b...
The formation of surface films on electrodes in contact with non-aqueous electrolytes in lithium-ion...
Despite the long-established rocking-chair theory of lithium-ion batteries (LIBs), developing novel ...
Compounds forming alloys with lithium, such as silicon or tin, are promising negative electrode mate...
The aging mechanisms of Li-ion batteries are introduced in this chapter, and are experimentally inve...
Lithium‐ion batteries are commonly used for electrical energy storage in portable devices and are pr...
The direct observation of the microstructural evolution and state-of-charge (SOC) distribution in ac...
Cell aging is a major issue in battery cells, as it affects the application capabilities. The mechan...
Understanding and improving the behavior of interfaces is essential to the development of safer and ...
Degradation mechanisms in 26 Ah commercial Li-ion battery cells comprising graphite as the negative ...
Lithium-ion batteries are the most ubiquitous energy storage devices in our everyday lives. However,...
Layered LiNi[subscript 0.8]Mn[subscript 0.1]Co[subscript 0.1]O[subscript 2](NMC811) is one of the hi...
Lithium- and manganese-rich layered-oxides (LMR-NMC) have potential application for electric vehicle...
The stability of electrode/electrolyte interfaces in Li-ion batteries is crucial to the performance,...
Lithium-ion technology is considered as outstanding candidate for implementation in high energy dens...
Energy storage technologies are crucial in the next green-energy transition. In particular, Li-ion b...
The formation of surface films on electrodes in contact with non-aqueous electrolytes in lithium-ion...
Despite the long-established rocking-chair theory of lithium-ion batteries (LIBs), developing novel ...
Compounds forming alloys with lithium, such as silicon or tin, are promising negative electrode mate...
The aging mechanisms of Li-ion batteries are introduced in this chapter, and are experimentally inve...
Lithium‐ion batteries are commonly used for electrical energy storage in portable devices and are pr...
The direct observation of the microstructural evolution and state-of-charge (SOC) distribution in ac...
Cell aging is a major issue in battery cells, as it affects the application capabilities. The mechan...
Understanding and improving the behavior of interfaces is essential to the development of safer and ...
Degradation mechanisms in 26 Ah commercial Li-ion battery cells comprising graphite as the negative ...
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