Multilayered sulfur composite cathodes for lithium sulfur batteries

What is claimed is: 1. A multilayered cathode for a lithium sulfur battery comprising: at least one current collector working electrode having a surface comprising a negatively charged carbon containing layer; two or more negatively charged sulfur containing layers wherein at least one of said negatively charged sulfur layers is a negatively charged sulfur-polystyrene sulfonate layer that is located in juxtaposition to and in communication with said negatively charged carbon containing layer; and at least one outermost layer comprising a positively charged polymer that is a polyaniline polymer for forming interconnected layers of said negatively charged sulfur-polystyrene sulfonate layer, said negatively charged carbon containing layer, and said positively charged polyaniline polymer, wherein said outermost layer is in juxtaposition to and in communication with at least one of said negatively charged sulfur layers. 2. The multilayered cathode of claim 1 wherein said negatively charged carbon containing layer comprises a carbon nanotube —COO − moiety. 3. The multilayered cathode of claim 1 comprising alternatively arranged layers of said negatively charged sulfur containing layers wherein said negatively charged sulfur containing layers comprise one or more negatively charged sulfur containing compounds and one or more negatively charged sulfur-polystyrene sulfonate layers. 4. The multilayered cathode of claim 1 wherein said layers have porous cross-linked structures. 5. The multilayered cathode of claim 1 wherein at least one of said sulfur containing layers is a sulfur-carbon nanotube polystyrene sulfonate polymer. 6. The multilayered cathode of claim 1 wherein said outermost layer of said positively charged polyaniline polymer is a sulfur polyaniline polymer. 7. A lithium sulfur battery having at least one multilayered cathode and at least one anode, wherein said multilayered cathode comprises at least one current collector working electrode having a surface comprising a negatively charged carbon containing layer; two or more negatively charged sulfur containing layers wherein at least one of said negatively charged sulfur layers is a negatively charged sulfur-polystyrene sulfonate layer that is located in juxtaposition to and in communication with said negatively charged carbon containing layer; and at least one outermost layer comprising a positively charged polymer that is a polyaniline polymer for forming interconnected layers of said negatively charged sulfur-polystyrene sulfonate layer, said negatively charged carbon containing layer, and said positively charged polyaniline polymer, wherein said outermost layer is in juxtaposition to and in communication with at least one of said negatively charged sulfur layers. 8. The lithium sulfur battery of claim 7 wherein said negatively charged carbon containing layer of said multilayered cathode comprises a carbon nanotube —COO − moiety. 9. The lithium sulfur battery of claim 7 wherein said multilayered cathode comprises alternatively arranged layers of said negatively charged sulfur containing layers wherein said sulfur containing layers comprise one or more negatively charged sulfur containing compounds and one or more negatively charged sulfur-polystyrene sulfonate layers. 10. The lithium sulfur battery of claim 7 wherein said layers of said multilayered cathode have porous cross-linked structures. 11. The lithium sulfur battery of claim 7 wherein at least one of said negatively charged sulfur containing layers of said multilayered cathode is a sulfur-carbon nanotube polystyrene sulfonate polymer. 12. The lithium sulfur battery of claim 7 wherein said outermost layer of said positively charged polyaniline polymer of said multilayered cathode is a sulfur polyaniline polymer. 13. A method of making a multilayered cathode for a lithium sulfur battery comprising: (a) providing a sulfur carbon nanotube polystrenesulfonate composition dispersed in water for forming a sulfur carbon nanotube polystyrene dispersion; (b) providing a sulfurized polyaniline composition dispersed in water for forming a sulfurized polyaniline dispersion; (c) providing a current collector having a surface comprising a carbon coating; (d) immersing said current collector having said carbon coating into said sulfurized polyaniline dispersion to form a sulfurized polyaniline coated current collector; and (e) immersing said sulfurized polyaniline coated current collector into said sulfur carbon nanotube polystyrene dispersion for forming one layer of said sulfurized polyaniline and said sulfur carbon nanotube polystyrenesulfonate treated current collector; and (f) repeating said steps (d) and (e) one or more times to form one or more additional layers of said sulfurized polyaniline and said sulfur carbon nanotube polystyrenesulfonate upon said treated current collector. 14. The method of claim 13 wherein said carbon coating comprises one or more of a functionalized porous carbon, graphite, grapheme, carbon nanoparticles, carbon nanotubes, carbon fibers, and carbon rods. 15. The method of claim 13 wherein said functionalized porous carbon is a carbon nanotube functionalized with a COO − group to form a carbon nanotube COO − . 16. The method of claim 13 wherein said current collector is one or more selected from the group consisting of an aluminum substrate, a copper substrate, a nickel substrate, and a conductive glass.