New ionic conductivity in solid, dimethylsiloxane-propylene oxide based on crosslinking copolymer networks containing li salt

Abstract EN

New ionic conductive elastomeric solid polymer has been prepared.

These elastomeric polymers have been prepared from networks of dimethylsiloxane-propylene oxide copolymer with lithium salt.

The ionic conductivity for the completed material exhibited VTF or WLF behavior in the temperature range - 120 to I00°C.

From a VTF analysis, ionic conductivity measurements over a similar temperature range are found to be consistent with the configuration entropy model for transport with a T0 parameter about 50°C below the "central" glass transition temperature Tg.New ionic conductive elastomeric solid polymer has been prepared.

These elastomeric polymers have been prepared from networks of dimethylsiloxane-propylene oxide copolymer with lithium salt.

The ionic conductivity for the completed material exhibited VTF or WLF behavior in the temperature range - 120 to I00°C.

From a VTF analysis, ionic conductivity measurements over a similar temperature range are found to be consistent with the configuration entropy model for transport with a T0 parameter about 50°C below the "central" glass transition temperature Tg.New ionic conductive elastomeric solid polymer has been prepared.

These elastomeric polymers have been prepared from networks of dimethylsiloxane-propylene oxide copolymer with lithium salt.

The ionic conductivity for the completed material exhibited VTF or WLF behavior in the temperature range - 120 to I00°C.

From a VTF analysis, ionic conductivity measurements over a similar temperature range are found to be consistent with the configuration entropy model for transport with a T0 parameter about 50°C below the "central" glass transition temperature Tg.New ionic conductive elastomeric solid polymer has been prepared.

These elastomeric polymers have been prepared from networks of dimethylsiloxane-propylene oxide copolymer with lithium salt.

The ionic conductivity for the completed material exhibited VTF or WLF behavior in the temperature range - 120 to I00°C.

From a VTF analysis, ionic conductivity measurements over a similar temperature range are found to be consistent with the configuration entropy model for transport with a T0 parameter about 50°C below the "central" glass transition temperature Tg.New ionic conductive elastomeric solid polymer has been prepared.

These elastomeric polymers have been prepared from networks of dimethylsiloxane-propylene oxide copolymer with lithium salt.

The ionic conductivity for the completed material exhibited VTF or WLF behavior in the temperature range - 120 to I00°C.

From a VTF analysis, ionic conductivity measurements over a similar temperature range are found to be consistent with the configuration entropy model for transport with a T0 parameter about 50°C below the "central" glass transition temperature Tg.