posted on 2020-02-05, 13:12authored byYi Cui, Jiayu Wan, Yusheng Ye, Kai Liu, Lien-Yang Chou
Safety
issues in lithium-ion batteries have raised serious concerns
due to their ubiquitous utilization and close contact with the human
body. Replacing flammable liquid electrolytes, solid-state electrolytes
(SSEs) is thought to address this issue as well as provide unmatched
energy densities in Li-based batteries. However, among the most intensively
studied SSEs, polymeric solid electrolyte and polymer/ceramic composites are usually
flammable, leaving the safety issue unattended. Here, we report the
first design of a fireproof, ultralightweight polymer–polymer
SSE. The SSE is composed of a porous mechanic enforcer (polyimide,
PI), a fire-retardant additive (decabromodiphenyl ethane, DBDPE),
and a ionic conductive polymer electrolyte (poly(ethylene oxide)/lithium
bis(trifluoromethanesulfonyl)imide). The whole SSE is made from organic
materials, with a thin, tunable thickness (10–25 μm),
which endorse the energy density comparable to conventional separator/liquid
electrolytes. The PI/DBDPE film is thermally stable, nonflammable,
and mechanically strong, preventing Li–Li symmetrical cells
from short-circuiting after more than 300 h of cycling. LiFePO4/Li half cells with our SSE show a high rate performance (131
mAh g–1 at 1 C) as well as cycling performance (300
cycles at C/2 rate) at 60 °C. Most intriguingly, pouch cells
made with our polymer–polymer SSE still functioned well even
under flame abuse tests.