Compositions and methods for prelithiating energy storage devices

What is claimed is: 1. A dry electrode film of an energy storage device, comprising: a dry active material; a dry binder; and a dry prelithiating material distributed throughout the dry active material and the dry binder, wherein the dry prelithiating material does not comprise elemental lithium metal; wherein the dry electrode film is free-standing and is substantially free of solvent residues, and wherein the dry prelithiating material comprises about 0.5-10 wt. % of the dry electrode film. 2. The dry electrode film of claim 1 , wherein the dry prelithiating material is selected from the group consisting of Li 2 O, Li 2 O 2 , Li 2 S, Li 3 N, LiN 3 , LiF, Li 5 FeO 4 , Li 2 NiO 2 , Li 6 CoO 4 , and Li 2 MoO 3 , or combinations thereof. 3. The dry electrode film of claim 1 , wherein the dry prelithiating material is Li 2 O 2 . 4. The dry electrode film of claim 1 , wherein the dry prelithiating material comprises about 1-3 wt. % of the dry electrode film. 5. The dry electrode film of claim 1 , wherein the dry active material is a dry cathode active material. 6. The dry electrode film of claim 5 , wherein the dry cathode active material comprises sulfur or a material comprising sulfur. 7. An energy storage device comprising the dry electrode film of claim 1 . 8. The energy storage device of claim 7 , wherein the energy storage device is a battery. 9. The dry electrode film of claim 1 , further comprising a dry conductive carbon additive, wherein a weight ratio of the dry prelithiating material and the dry conductive carbon additive is within a range of about 10:1 to about 1:1. 10. The dry electrode film of claim 1 , wherein the dry prelithiating material comprises submicron sized particles. 11. The dry electrode film of claim 1 , wherein the dry binder comprises particles of about 50 nm to about 10 μm in size. 12. A dry method of fabricating a dry electrode film of an energy storage device, comprising: mixing a dry prelithiating material and a dry conductive carbon additive to form a first dry mixture wherein the dry prelithiating material does not comprise elemental lithium metal; mixing the first dry mixture with a dry active material to form a second dry mixture; adding a dry fibrillizable binder to the second dry mixture to form a dry electrode film mixture; and fibrillizing the dry fibrillizable binder in the dry electrode film mixture; wherein the dry method is a dry fabrication process substantially free of solvents wherein the dry electrode film is free-standing, and wherein the dry prelithiating material comprises about 0.5-10 wt. % of the dry electrode film. 13. The dry method of claim 12 , further comprising calendering the dry electrode film mixture to form the free-standing dry electrode film. 14. The dry method of claim 13 , further comprising disposing the free- standing dry electrode film over a current collector to form an electrode. 15. The dry method of claim 14 , further comprising: incorporating the electrode into an energy storage device; and performing an initial cycling of the energy storage device, thereby oxidizing the dry prelithiating material. 16. The dry method of claim 12 , wherein mixing the first dry mixture with the dry active material further comprises mixing a dry carbon material and a dry conductive carbon material to form the second dry mixture. 17. The dry method of claim 12 , wherein mixing the dry prelithiating material and the dry conductive carbon additive is performed so that a temperature of the first dry mixture is at most about 150° C. 18. The dry method of claim 12 , wherein mixing the dry prelithiating material and the dry conductive carbon additive is performed so that the temperature of the first dry mixture is at most about 100° C. 19. The dry method of claim 12 , wherein mixing the dry prelithiating material and the dry conductive carbon additive results in electrical contact between primary particles of the dry prelithiating material and the dry conductive carbon additive. 20. The dry method of claim 12 , wherein mixing the dry prelithiating material and the dry conductive carbon additive is performed such that a temperature of the first dry mixture is at most about 200° C. 21. The dry method of claim 12 , wherein a ratio of the dry prelithiating material and the dry conductive carbon additive is within a range of about 10:1 to about 1:1. 22. The dry method of claim 12 , wherein a ratio of the dry prelithiating material and the dry conductive carbon additive is within a range of about 5:1 to about 5:3. 23. The dry method of claim 12 , wherein mixing the first dry mixture and the dry active material is performed so that the temperature of the second dry mixture is at most about 100° C.