Visualizing the growth process of sodium microstructures in sodium batteries by in-situ 23Na MRI and NMR spectroscopy

“…We believe that our understanding based on LiH and H 2 will draw forth more insightful efforts to realize excellent Li protection and the ultimate practical applications of “holy grail” LMBs. More importantly, our perspectives from metal hydrides will open a new era of understanding battery interface reactions and interface components, are quite meaningful to conventional state‐of‐art lithium (or sodium)‐ion batteries, lithium‐oxygen batteries, lithium‐sulfur batteries and other‐type metal batteries (such as sodium‐metal, [33] potassium‐metal, and calcium‐metal batteries, etc. ).…”

The Formation/Decomposition Equilibrium of LiH and its Contribution on Anode Failure in Practical Lithium Metal Batteries

“…We believe that our understanding based on LiH and H 2 will draw forth more insightful efforts to realize excellent Li protection and the ultimate practical applications of “holy grail” LMBs. More importantly, our perspectives from metal hydrides will open a new era of understanding battery interface reactions and interface components, are quite meaningful to conventional state‐of‐art lithium (or sodium)‐ion batteries, lithium‐oxygen batteries, lithium‐sulfur batteries and other‐type metal batteries (such as sodium‐metal, [33] potassium‐metal, and calcium‐metal batteries, etc. ).…”

The Formation/Decomposition Equilibrium of LiH and its Contribution on Anode Failure in Practical Lithium Metal Batteries

“…Combining with Magnetic resonance imaging (MRI), the microstructures including dendrite and mossy metal deposition can also be characterized. 121 In addition, sodium hydride NaH was also discovered as one of SEI components on the surface of sodium metal with NMR. 121 In operando real-time mass spectrometric technique has also been used to reveal the dynamic double-layer SEI, where the inner SEI is a thin and denser inorganic rich layer that functions as Li-ion conductor and electron insulation, and the outer layer is organic-rich compound.…”

“…121 In addition, sodium hydride NaH was also discovered as one of SEI components on the surface of sodium metal with NMR. 121 In operando real-time mass spectrometric technique has also been used to reveal the dynamic double-layer SEI, where the inner SEI is a thin and denser inorganic rich layer that functions as Li-ion conductor and electron insulation, and the outer layer is organic-rich compound. 122 Both the formation of SEI and orphaning lithium will cause the lithium metal loss reversibility.…”

Stabilizing metal battery anodes through the design of solid electrolyte interphases

“…[ 4,5 ] During the repeated plating/stripping processes, the huge volume variety of Na anode unavoidably causes the fracture of SEI layer; thus the newly exposed metallic Na will be consumed in constant contact with the electrolyte, finally leading to the depletion of electrolyte and poor Coulombic efficiency (CE). [ 6,7 ] 2) More seriously, the formation and growth of Na dendrites during cycles easily induce the short circuit, overheating or even explosion of battery accompany with the penetration of dendrites through separator to reach the cathode. [ 8,9 ] Relative researches indicate that the emergence of Na dendrites is mainly induced by the uneven distribution of Na + ions, high local current density, and heterogeneous nucleation of Na.…”

Interfacial Protection Engineering of Sodium Nanoparticles toward Dendrite‐Free and Long‐Life Sodium Metal Battery