@article{Luo2025, 
author = {Haihua Luo and Jintao Du and Jingjing Fu and Qing Zhang and Xinfang Hu and Bo Liu and Wenhua Zhang},
title = {Phase-regulated ultrathin PVDF-based electrolytes for dynamic dendrite suppression in solid-state lithium metal batteries},
year = {2025},
journal = {Nano Research},
volume = {18},
number = {8},
pages = {94907631},
keywords = {piezoelectric effects, solvation structures, ultrathin solid-state electrolytes, oriented MXene, dynamically promoted Li deposition},
url = {https://www.sciopen.com/article/10.26599/NR.2025.94907631},
doi = {10.26599/NR.2025.94907631},
abstract = {The pursuit of safer batteries has driven significant research efforts toward solid-state lithium metal cells. To achieve an energy density comparable to that of liquid electrolyte-based cells, the development of ultrathin and lightweight solid electrolytes with superior performance is essential. However, fabricating solid electrolytes with thicknesses comparable to those of commercial separators (~ 10 μm) used in liquid systems remains challenging because of the increased risk of short circuits caused by dendrite growth. In this study, we present a polymer-based solid-state electrolyte composed of a 7.3 μm-thick ultrathin poly(vinylidene fluoride) (PVDF) film embedded with highly oriented Ti3C2Tx (Tx represents abundant surface functional groups) nanoflakes. Functionalized nanoflakes induce PVDF β-phase formation through hydrogen bonding, significantly improving dielectric and piezoelectric properties. These improvements enable a Li+ transfer number of 0.83 and ~ 10-fold enhancement in piezoelectric response. A high Li+ transfer number reduces polarization by suppressing space-charge formation during Li plating. Simultaneously, when the electrolyte senses strain accumulation from inevitable Li protrusions, the piezoelectric-induced electric field promptly alleviates the localized overpotential, dynamically promoting uniform Li deposition. Consequently, these electrolytes exhibit exceptional compatibility with Li anode, enabling long-term cycling under various conditions. The symmetric Li||Li cells demonstrate stable operation for over 3000 h without any micro-short circuits, whereas the LiFePO4||Li full cells maintain high Coulombic efficiency (&gt; 99.7%) and good stability through 300 cycles at 1 C.}
}