Affiliation:
1. Zhejiang University
2. Xi’an Technological University
3. Fudan University
Abstract
Abstract
The use of solid-state electrolytes in all-solid-state batteries is a prospective technology for increasing energy densities. However, poor oxidative stability and issues with the dendrite significantly hamper their applicability. LiBH4 is considered as one of the most promising candidates due to its irreplaceable thermodynamic stability to Li. Herein, an in situ melting reaction is proposed to generate the covalently bonded coordination on the particle surfaces of electrolytes to resolve those issues. This coordination thermodynamically shuts down the electronic exchanges during the anionic oxidation decomposition by covalently bonding the local high-concentration electrons on the anions, and it kinetically blocks electronic percolation on the particle surfaces of electrolytes; this phenomenon leads to an unprecedented voltage window (0 ~ 10 V) with a peak oxidation current that is 370 times lower and an electronic conductivity that is 3 orders of magnitude lower than the counterpart at 25 ℃. The coordination can act as a binder to bond electrolyte particles, achieving a remarkable Young’s modulus of 208.45 GPa; this modulus is twice as high as the counterpart to adapt the sustained stress-strain release in Li plating and stripping. With these merits, the electrolyte displays a record-breaking critical current density of 21.65 mA cm− 2 at 25 ℃ (twice the best-reported data in Li-ion solid-state electrolytes), cycling stabilities under 10.83 mA cm− 2 for 6000 h and 10 V for 1000 h, and an operational temperature window of -30 to 150 ℃. Their Li-LiCoO2 cells exhibit superior reversibility under high voltage. Our findings illuminate a clear direction for oxidative stability and dendrite suppression in solid-state electrolytes, making tremendous progress in high-voltage lithium batteries.
Publisher
Research Square Platform LLC