Anode electrode compositions for battery applications

What is claimed is: 1. An electrode composition, comprising: an active anode material; and at least one material selected from the group consisting of: carbon nanostructures, fragments of carbon nanostructures and fractured multiwall carbon nanotubes, wherein the active anode material includes graphite, silicon, SiO x , silicon-graphite composite or lithium titanate wherein the carbon nanostructures or fragments of carbon nanostructures include a plurality of multiwall carbon nanotubes that are crosslinked in a polymeric structure by being branched, interdigitated, entangled and/or sharing common walls, and wherein the fractured multiwall carbon nanotubes are derived from carbon nanostructures and are branched and share common walls with one another. 2. The electrode composition of claim 1 , wherein: at least one of the multiwall carbon nanotubes has a length equal to or greater than 2 microns, as determined by SEM, at least one of the multiwall carbon nanotubes has a length to diameter aspect ratio within a range of from 200 to 1000, there are at least two branches along a 2-micrometer length of at least one of the multiwall carbon nanotube, as determined by SEM, at least one multiwall carbon nanotube exhibits an asymmetry in the number of walls observed in the area after a branching point relative to the area prior to the branching point, and/or no catalyst particle is present at or near branching points, as determined by TEM. 3. The electrode composition of claim 1 , wherein the multiwall nanotubes include 2 to 30 coaxial nanotubes, as determined by TEM at a magnification sufficient for counting the number of walls. 4. The electrode composition of claim 1 , wherein at least 1% of the carbon nanotubes have a length equal to or greater than 2 microns, as determined by SEM, a length to diameter aspect ratio within a range of from 200 to 1000, and/or exhibit an asymmetry in the number of walls observed in the area after a branching point relative to the area prior to the branching point. 5. The electrode composition of claim 1 , wherein the composition further includes a binder. 6. The composition of claim 5 , wherein the binder is polyvinylidene difluoride, or carboxymethylcellulose and styrene butadiene rubber. 7. The electrode composition of claim 1 , wherein the composition is a paste, a slurry or a solid. 8. The electrode composition of claim 7 , wherein the composition further includes a solvent. 9. The electrode composition of claim 8 , wherein the solvent is N-methylpyrrolidone, acetone, an alcohol, water, or any combination thereof. 10. The electrode composition of claim 1 , wherein the electrode composition, when dried, contains carbon nanostructures, carbon nanostructure fragments and/or fractured multiwall nanotubes in an amount no greater than about 5% by weight. 11. The electrode composition of claim 1 , wherein the carbon nanostructures are coated carbon nanostructures. 12. The electrode composition of claim 11 , wherein the coated carbon nanostructures are polyurethane-coated nanostructures or polyethylene glycol-coated carbon nanostructures. 13. The electrode composition of claim 11 , wherein a weight of the coating relative to the weight of the coated carbon nanostructures is within the range of from about 0.1% to about 10%. 14. The electrode composition of claim 11 , wherein the electrode composition, when dried, contains coated carbon nanostructures, fragments of coated carbon nanostructures and/or fractured multiwall carbon nanotubes derived from the coated carbon nanostructures in an amount no greater than about 5 wt %. 15. The electrode composition of claim 1 , comprising the active anode material in an amount of from 80 to 99 weight %. 16. The electrode composition of claim 1 , further comprising a carbon conductive additive selected from the group consisting of carbon black, individualized carbon nanotubes in pristine form and any combination thereof. 17. The electrode composition of claim 1 , further comprising a carbon black, wherein the carbon black has a BET area of 200 m 2 /g or less and an OAN of at least 130 mL/100 g. 18. The electrode composition of claim 1 , wherein the carbon nanostructures and the fragments of carbon nanostructures are free of a growth substrate. 19. A battery comprising a composition according to claim 1 . 20. A method for preparing an electrode composition, the method comprising: combining a dispersion, which includes at least one material selected from the group consisting of carbon nanostructures, fragments of carbon nanostructures and fractured multiwall carbon nanotubes, with an active anode material, to form the electrode composition, wherein the carbon nanostructures or fragments of carbon nanostructures include a plurality of multiwall carbon nanotubes that are crosslinked in a polymeric structure by being branched, interdigitated, entangled and/or sharing common walls, wherein the fractured multiwall carbon nanotubes are derived from carbon nanostructures and are branched and share common walls with one another, and wherein the active anode material includes graphite, silicon, SiO x , silicon-graphite composite or lithium titanate. 21. The method of claim 20 , wherein: at least one of the multiwall carbon nanotubes has a length equal to or greater than 2 microns, as determined by SEM, at least one of the multiwall carbon nanotubes has a length to diameter aspect ratio within a range of from 200 to 1000, there are at least two branches along a 2-micrometer length of at least one of the multiwall carbon nanotube, as determined by SEM, at least one multiwall carbon nanotube exhibits an asymmetry in the number of walls observed in the area after a branching point relative to the area prior to the branching point, and/or no catalyst particle is present at or near branching points, as determined by TEM. 22. A method for preparing an electrode composition, the method comprising incorporating carbon nanostructures in a slurry which includes an active anode material to form the electrode composition, wherein the active anode material includes graphite, silicon, SiO x , silicon-graphite composite or lithium titanate, and wherein a carbon nanostructure comprises a plurality of multiwall carbon nanotubes that are crosslinked in a polymeric structure by being branched, interdigitated, entangled and/or sharing common walls. 23. The method of claim 22 , wherein: at least one of the multiwall carbon nanotubes has a length equal to or greater than 2 microns, as determined by SEM, at least one of the multiwall carbon nanotubes has a length to diameter aspect ratio within a range of from 200 to 1000, there are at least two branches along a 2-micrometer length of at least one of the multiwall carbon nanotube, as determined by SEM, at least one multiwall carbon nanotube exhibits an asymmetry in the number of walls observed in the area after a branching point relative to the area prior to the branching point, and/or no catalyst particle is present at or near branching points, as determined by TEM.