Enabling extreme fast charging [PDF]
The need to prevent lithium plating makes battery recharging a slow process. Three pathways are established to facilitate extreme fast charging (XFC): new electrodes and electrolytes, charging protocol optimization, and thermal management intervention. In a recent issue of Nature Communications, Zeng et al.
Tao Zhu +3 more
openaire +4 more sources
Perceived Usage Potential of Fast-Charging Locations [PDF]
Fast-charging infrastructure with charging time of 20–30 min can help minimizing current perceived limitations of electric vehicles, especially considering the unbalanced and incomprehensive distribution of charging options combined with a long perceived charging time. Positioned on optimal location from user and business perspective, the technology is
Krause, Julia +5 more
openaire +4 more sources
Fast charging stations with stationary batteries: A techno-economic comparison of fast charging along highways and in cities [PDF]
Fast charging infrastructure is widely acknowledged as necessary for the market success of electric vehicles. However, fast charging requires cost intensive infrastructure and grid connections. Accordingly, the risk of sunk cost is high, although fast charging infrastructure might be profitable in the medium to long term.
Funke, Simon +3 more
core +6 more sources
Extreme fast charging and stable cycling of LiMn2O4 – Li4Ti5O12 lithium batteries by suppression of cathode phase changes [PDF]
Extreme fast charging (XFC, i.e., achieving at least 80% state of charge within 15 minutes) remains as a high-desirability criterion for next-generation lithium batteries.
Patrick, Howlett +10 more
core +1 more source
Fast-Charging Degradation Mechanism of Two-Dimensional FeSe Anode in Sodium-Ion Batteries [PDF]
Transition-metal chalcogenides (TMCs) are recognized as promising sodium-ion battery anodes for their high theoretical specific capacity and low sodium metal plating risk. Nevertheless, their unsatisfactory rate capability along with unstable cyclability
Jingjing Wang (140791) +19 more
core +1 more source
Fast-Charging Aging Considerations: Incorporation and Alignment of Cell Design and Material Degradation Pathways [PDF]
Fast charging of batteries for electric vehicles is seen as one of the most direct ways to enhance adoption. Currently, fast charging is limited by increased cell aging, which is primarily driven by Li plating and degradation of cathode materials.
Bor-Rong Chen +21 more
core +1 more source
The Effect of Cycling on the State of Health of the Electric Vehicle Battery [PDF]
This paper provides an analysis of the experimental results available for lithium ion battery degradation which has been used to create a model of the effect of the identified parameters on the ageing of an EV battery.
Ghanim Putrus +7 more
core +1 more source
Fast-Charging Capability of Thin-Film Prussian Blue Analogue Electrodes for Aqueous Sodium-Ion Batteries [PDF]
Prussian blue analogues are considered as promising candidates for aqueous sodium-ion batteries providing a decently high energy density for stationary energy storage.
Tim Steeger +23 more
core +1 more source
An Online Mechanism for Multi-Speed Electric Vehicle Charging [PDF]
As plug-in electric vehicles become more widespread, their charging needs to be coordinated, in order to ensure that capacity constraints are not exceeded.
Enrico H. Gerding +14 more
core +1 more source
An Elastic Charging Service Fee-Based Load Guiding Strategy for Fast Charging Stations
Compared with the traditional slow charging loads, random integration of large scale fast charging loads will exert more serious impacts on the security of power network operation.
Shu Su +3 more
doaj +1 more source

