Ceramic/polymer　composite　solid　electrolytes　are　emerging　as　a　good　strategy　to　improve　the　safety　and　the　power　density　of　next-generation　battery　technologies.　This　battery　technology　is,　however,　limited　by　the　high　interfacial　resistance　across　the　ceramic/polymer　interface　at　room　temperature.　Herein,　an　efficient　strategy　was　proposed　to　lower　the　interfacial　resistance　via　building　a　“bridge”　between　polymer　phase　and　ceramic　phase　in　the　prepared　composite　solid　electrolyte　(CSE)　and　increase　its　electrochemical　window.　The　prepared　composite　solid　electrolyte　possessed　a　high　ionic　conductivity　of　3.1　×　10−3　S　cm−1　at　room　temperature　via　forming　an　extra　high-speed　Li-ion　pathway　between　poly(vinyl　ethylene　carbonate)　(PVEC)　polymer　phase　and　ceramic　phase　(LLZTO)　by　the　aid　of　the　formed　chemical　bonds　and　hydrogen　bonds.　Lithium　symmetrical　batteries　based　on　CSE　exhibit　a　reduced　charge　voltage　polarization　and　cycled　almost　1000　h　at　0.1　mA/cm2　without　the　occurrence　of　short　circuits.　This　“bridge”　strategy　provides　an　effective　way　to　resolve　the　problem　of　high　interfacial　resistance　and　interface　compatibility.　©　2023　Elsevier　B.V.