High melt temperature microporous lithium-ion rechargeable battery separators and methods of preparation and use

The invention claimed is: 1. A high melt temperature microporous battery separator for a lithium-ion rechargeable battery comprising: a microporous membrane, said microporous membrane being a stretched thermoplastic polymer film or sheet, said thermoplastic polymer consisting of a polyolefin selected from the group consisting of: polyethylene, polypropylene, polymethylpentene, and combinations thereof; and a coating on at least one entire side of said microporous membrane comprising a high glass transition temperature (T g ) polymer, wherein said high glass transition temperature (T g ) polymer being polybenzimidazole (PBI) or blends of PBI with one or more other polymers, said coating has a dimensional or structural integrity to prevent contact between an anode and a cathode of the lithium-ion rechargeable battery, and prevents contact between the anode and cathode when the lithium-ion rechargeable battery is maintained at elevated temperatures for at least a period of time. 2. The high melt temperature microporous battery separator of claim 1 wherein said high glass transition temperature (T g ) polymer having a glass transition temperature (T g ) greater than 165° C. 3. The high melt temperature microporous battery separator of claim 1 wherein said high glass transition temperature (T g ) polymer having a glass transition temperature (T g ) greater than 180° C. 4. The high melt temperature microporous battery separator of claim 1 wherein said high glass transition temperature (T g ) polymer having a glass transition temperature (T g ) of at least 250° C. 5. The high melt temperature microporous battery separator of claim 1 wherein said high glass transition temperature (T g ) polymer being soluble in at least one volatile solvent. 6. The high melt temperature microporous battery separator of claim 1 wherein said other polymers being selected from the group consisting of: polyimides, polyamideimides, polysulfones, polyketones, and combinations thereof. 7. The high melt temperature microporous battery separator of claim 1 wherein said coating further comprising fumed alumina. 8. The high melt temperature microporous battery separator of claim 1 , wherein the coating was applied as a coating solution or slurry of PBI, alumina particles, and DMAc. 9. The high melt temperature microporous battery separator of claim 1 , wherein said microporous membrane being at least one of a polyolefin membrane, a polypropylene membrane, a polyethylene membrane, and a trilayer separator. 10. The high melt temperature microporous battery separator of claim 1 wherein said microporous membrane being manufactured by a dry stretch process or a wet process. 11. The high melt temperature microporous battery separator of claim 1 wherein said microporous membrane being a single layer membrane, a bi-layer membrane, a tri-layer membrane, or a multi-layer membrane. 12. The high melt temperature microporous battery separator of claim 1 , wherein said microporous membrane having a pre-treatment adapted for altering the surface characteristics of the membrane and improving the adhesion of the high T g polymer coating to the membrane, wherein said pre-treatment being on one or both sides of said microporous membrane and being selected from the group consisting of: priming, stretching, corona treatment, plasma treatment, coating such as surfactant coatings, and combinations thereof. 13. The high melt temperature microporous battery separator of claim 1 , wherein said high T g polymer coating being applied to said microporous membrane by one of: a coating step followed by an immersion step, and wherein the high T g coated membrane is immersed into a gelation bath to both precipitate the high T g polymer and to remove the solvent for high T g polymer in order to form a high T g porous coating or layer, or a coating step followed by an immersion step wherein the high T g coated membrane is immersed into a bath to precipitate the high T g polymer. 14. The high melt temperature microporous battery separator of claim 1 wherein said battery separator having a melt temperature of >160° C. 15. The high melt temperature microporous battery separator of claim 1 wherein said battery separator having a melt temperature of >250° C. 16. The high melt temperature microporous battery separator of claim 1 , wherein the coating was applied as a plurality of high glass transition temperature (T g ) polymer nanofibers being electrospun onto at least one side of said microporous membrane. 17. In a lithium-ion rechargeable battery, the improvement comprising the high melt temperature microporous battery separator of claim 1 . 18. The high melt temperature microporous battery separator of claim 1 , wherein said coating on at least one side of said microporous membrane comprising a plurality of polymer nanofibers on said microporous membrane, said polymer having a glass transition temperature (T g ) of at least 160° C. 19. The high melt temperature microporous battery separator of claim 1 , wherein said microporous membrane comprising a polymer or blend, said polymer or blend having a glass transition temperature (T g ) of at least 160° C.; whereby, said microporous membrane being capable of retaining its physical structure up to 250° C. in a lithium-ion rechargeable battery, cell, pack, battery, accumulator, or capacitor. 20. A battery comprising the battery separator of claim 1 .