A review of thermal physics and management inside lithium-ion batteries for high energy density and fast charging

Abstract: Traditionally it has been assumed that battery thermal management systems should be designed to maintain the battery temperature around room temperature. That is not always true as Lithium-ion battery (LIB) R&D is pivoting towards the development of high energy density and fast charging batteries. Therefore, it is necessary to have a comprehensive review of thermal considerations for LIBs targeted for high energy density and fast charging, i.e., the optimal thermal condition, thermal physics (heat transport an… Show more

“…For example, there is significant interest in using solar thermal processes to decarbonize industrial heating; it is expected that industrial processes requiring medium temperature (<∼150°C) heat can be economically decarbonized using solar thermal processes. For high-power microelectronics ( Sohel Murshed and Nieto de Castro, 2017 ) and high-energy-density and fast-charging lithium ion batteries ( Zeng et al., 2021 ), thermal management plays a very important role for reliable operation of these technologies. Other examples of thermal management include cooling of both traditional ( Meshkatodd, 2008 ) and solid state ( She et al., 2013 ) electrical transformers.…”

Thermal fluids with high specific heat capacity through reversible Diels-Alder reactions

“…For example, there is significant interest in using solar thermal processes to decarbonize industrial heating; it is expected that industrial processes requiring medium temperature (<∼150°C) heat can be economically decarbonized using solar thermal processes. For high-power microelectronics ( Sohel Murshed and Nieto de Castro, 2017 ) and high-energy-density and fast-charging lithium ion batteries ( Zeng et al., 2021 ), thermal management plays a very important role for reliable operation of these technologies. Other examples of thermal management include cooling of both traditional ( Meshkatodd, 2008 ) and solid state ( She et al., 2013 ) electrical transformers.…”

Thermal fluids with high specific heat capacity through reversible Diels-Alder reactions

“…In recent years, with the ever-rising requirements of electric vehicles, unmanned aerial vehicles, radio communications, medical devices, portable electronic devices and other precision devices for light-weight and small-sized power sources, more emphasis has been placed on the energy density of lithium ion batteries (LIBs). 1,2 Compared with commercial graphite anode materials (only 372 mA h g À1 /830 mA h cm À3 ), transition metal phosphides (TMPs, M ¼ Co, Fe, Ni, Cu, etc.) have become one of the most promising anode materials in view of their high theoretical capacity (e.g.…”

In situ construction of flower-like CoP-in-carbon anode materials for high-rate and long-term lithium ion batteries

“…3,[7][8][9][10][11] Even so, the stoichiometric Nb2O5 is an insulator with a wide bandgap (between 3.2 and 4.0 eV) which engenders poor electronic conductivity (σ ~ 3×10 -6 S cm -1 at 300 K), thereby improving the poor electronic conductivity is key to achieve a high-rate performance of Nb2O5 which eventually facilitate the realization of fast rechargeable energy devices. [12][13][14] To overcome the drawback, considerable efforts have been devoted to investigating fabrication techniques such as building special morphology, introducing conductive carbon networks, doping foreign elements for adequate utilization, and nanoarchitecture current collector (see Table S1 † for representative modification of the reported Nb2O5-based materials). [15][16][17][18][19][20][21][22][23][24][25][26][27][28][29][30] Although materials with utilization of these methods show certain enhancement, the compatibility with the ongoing manufacturing line remains challenging to meet the requirement of practical utilization of as mentioned methods.…”

Inducing Conductive Surface Layer on Nb2O5 via Ar-ion Bombardment: Enhanced Electrochemical Performance for Li-ion Batteries