Separators for high voltage rechargeable lithium batteries and related methods

We claim: 1 ) Improved or novel membranes or separators for a high energy and/or high voltage rechargeable lithium battery which is stable over 4.5 volts and comprises at least one porous membrane comprising at least one of embedded particles, a novel polymer, and a ceramic coating on at least one side. 2 ) The membrane of claim 1 being stable up to at least 4.6 volts. 3 ) The membrane of claim 1 being stable up to at least 4.7 volts. 4 ) The membrane of claim 1 being stable up to at least 5.0 volts. 5 ) The membrane of claim 1 being stable up to up to a 5.0 volt or higher charging voltage. 6 ) The membrane of claim 1 being a novel or improved single or multilayer or multiply microporous separator membrane. 7 ) The membrane of claim 1 being at least one of a microporous separator membrane for a high energy lithium ion battery which is stable up to a 5 volt charging voltage, a thermal shutdown membrane with high temperature thermal stability which is designed to facilitate an increase in the overall energy density of a high energy lithium ion battery, a polymer separator membrane which uses a novel embedded ceramic material to achieve a 5 volt charging voltage capability in a lithium ion rechargeable battery, and a microporous separator membrane that supports the future development trend towards a high energy battery for consumer electronic applications or for a high energy battery lithium ion battery capable of achieving an extended driving range in electric vehicle applications. 8 ) The membrane of claim 1 being a microporous battery separator membrane comprising a polymer containing an embedded ceramic material whereby the ceramic-containing polymer microporous battery separator membrane has a 5 volt charging voltage capability in a lithium ion rechargeable battery. 9 ) The membrane of claim 8 being a polyolefin microporous battery separator membrane. 10 ) The membrane of claim 8 being a non-polyolefin microporous battery separator membrane. 11 ) The membrane of claim 8 wherein said polymer microporous battery separator membrane has a thermal shutdown function. 12 ) The membrane of claim 11 wherein said polymer microporous battery separator membrane has a high temperature stability up to 165° C. 13 ) The membrane of claim 12 wherein said polymer microporous battery separator membrane has a high temperature stability up to 180° C. 14 ) The membrane of claim 13 wherein said polymer microporous battery separator membrane has a high temperature stability ≧180° C. 15 ) The membrane of claim 8 wherein the microporous battery separator membrane has greater than or equal to a 5 volt charging voltage capability in a lithium ion rechargeable battery. 16 ) In a rechargeable lithium battery, the improvement comprising the microporous battery separator membrane of claim 8 . 17 ) In an electric drive vehicle, the improvement comprising the microporous battery separator membrane of claim 8 . 18 ) The membrane of claim 8 wherein the embedded ceramic material is selected from the group of ceramic particles, aluminum oxide, boehmite, barium, barium sulfate, X-ray detectable elements, metal, metal oxide, metal phosphate, metal carbonate, X-ray fluorescent material, metal salt, metal sulfate, or mixtures thereof, and any of the foregoing metals being selected from the group consisting of Zn, Ti, Mn, Ba, Ni, W, Hg, Si, Cs, Sr, Ca, Rb, Ta, Zr, Al, Pb, Sn, Sb, Cu, Fe, and mixtures thereof. 19 ) A non-polyolefin microporous battery separator membrane which consists of one or more non-polyolefin polymers and which has a oxidation stability at a 5 volt charge voltage in a lithium rechargeable battery. 20 ) The membrane of claim 19 wherein said membrane is used as a component of an electrochemical device, a capacitor, a super capacitor, a double layer capacitor, a primary battery, or a secondary battery. 21 ) The membrane of claim 1 wherein said membrane is a lithium secondary battery separator that is stable against oxidation in a lithium ion battery with a cell voltage up to or equal to 5.0 volts, wherein cell voltage may be a measure of the potential difference between two electrodes (positive electrode and negative electrode) in an electrochemical cell.