A high-temperature lithiumcopper oxide cell with a solid polymer electrolyte

The cycling performance of a lithium-manganese oxide spinet (prepared from Mn0 2 and Li2CO 3) has been investigated as a function of preparation temperature m a lithium polymer electrolyte cell Excellent reversibility and high rate performance have been observed from a spmel phase prepared at 450 °C

Many sulphate mixtures are suitable as electrolytes for high temperature all-solid batteries, and it is possible to use easily available metals such as magnesium, calcium or zinc as the anode. We have previously shown that not only the theoretical energy density, but also the obtained power density,

## Abstract Polymer electrolyte fuel cell stacks assembled with Johnson Matthey Fuel Cells and SolviCore MEAs based on the Aquivion™ E79‐03S short‐side chain (SSC), chemically stabilised perfluorosulphonic acid membrane developed by Solvay Solexis were investigated at CNR‐ITAE in the EU Sixth Frame

The lithium ionic conductivity of materials prepared by reaction of lithium iodide with anhydrous and hydrated aluminum sulfate has been investigated by a.c. conductivity and n.m.r, techniques. The a.c. measurements indicated thermally activated diffusion with an activation energy of 8.3 kcal/ tool.

Cells containing either LiClO,/poly(ethylene oxide) or LiCF,SO,/ poly(ethylene oxide) complexes as the electrolyte with lithium metal and/or V601s-based composite electrodes have been assembled and their a.c. impedance measured at temperatures in the range of room temperature to 120 "c. Two resista