Curved two-dimensional nanocomposites for battery electrodes

The invention claimed is: 1. A battery electrode composition, comprising: a composite material comprising one or more nanocomposites, wherein the one or more nanocomposites each have a curved planar geometry and comprise: a planar substrate backbone having a curved geometrical structure with a curvature that is selected based upon a volume expansion characteristic of the active material, and an active material forming a non-porous, continuous or substantially continuous film at least partially encasing the substrate backbone, wherein the film has an average thickness on either side of the substrate backbone in the range of 1.4 nm to 200 nm, and wherein the active material stores metal ions within the film and is subject to volume changes greater than about 5% upon insertion or extraction of the metal ions, wherein the one or more nanocomposites comprise a plurality of electrically-interconnected nanocomposites aggregated into a three-dimensional agglomeration, wherein the three-dimensional agglomeration comprises internal pores that are left vacant and have a total porosity in the three-dimensional agglomeration that is defined by the curvatures of the planar substrate backbones of the plurality of electrically-interconnected nanocomposites so as to be sufficient to accommodate the volume changes in the active material that are greater than about 5% upon insertion or extraction of the metal ions. 2. The battery electrode composition of claim 1 , wherein the active material comprises at least one of silicon (Si), germanium (Ge), tin (Sn), titanium (Ti), magnesium (Mg), phosphorus (P), lithium (Li), sulfur (S), fluorine (F), or iodine (I). 3. The battery electrode composition of claim 1 , wherein the curved geometrical structure of the substrate backbone of each of the one or more nanocomposities is characterized by a width-to-thickness aspect ratio in the range of about 10 to about 1,000,000, with an average thickness of the substrate backbone of each of the one or more nanocomposities in the range of about 0.2 nm to about 100 nm, and wherein at least a portion of the substrate backbone of each of the one or more nanocomposities has a radius of curvature in the range of about 0.3 nm to about 0.03 mm. 4. The battery electrode composition of claim 1 , wherein the substrate backbone of each of the one or more nanocomposities comprises an exfoliated layered material. 5. The battery electrode composition of claim 4 , wherein the exfoliated layered material comprises a single- or multi-layer graphene sheet. 6. The battery electrode composition of claim 1 , wherein the substrate backbone of each of the one or more nanocomposities is curved or rolled into a substantially helical or spiral shape. 7. The battery electrode composition of claim 1 , wherein the three-dimensional agglomeration is a substantially spherical or ellipsoidal granule. 8. The battery electrode composition of claim 1 , wherein the internal pores are at least partially filled with an ionically conductive material having an ionic conductivity of at least 10 −8 S cm −1 . 9. The battery electrode composition of claim 8 , wherein the ionically conductive material is a solid electrolyte. 10. The battery electrode composition of claim 8 , wherein the ionically conductive material is also electrically conductive with an electrical conductivity of at least 10 −8 S cm −1 . 11. The battery electrode composition of claim 10 , wherein the ionically and electrically conductive material is a composite mixture of a first material that is more ionically conductive and a second material that is more electrically conductive, relative to each other. 12. The battery electrode composition of claim 1 , further comprising: a protective coating at least partially encasing each nanocomposite, wherein the protective coating is a Li-ion permeable and electrolyte solvent impermeable material comprising a polymer, a metal oxide, a metal fluoride, a sulfide, a carbon, or a combination thereof. 13. The battery electrode composition of claim 12 , wherein the protective coating forms a mechanically stable and plastically deformable shell around the active material. 14. The battery electrode composition of claim 13 , further comprising a carbon-based layer disposed between the protective coating shell and the active material, wherein at least one pore is disposed between the protective coating shell and the active material when the active material is in a delithiated state to accommodate volume changes in the active material core during lithiation. 15. The battery electrode composition of claim 1 , wherein the volume changes in the active material that are accommodated by the internal pores range between about 300% and about 400% upon insertion or extraction of the metal ions. 16. A Li-ion battery comprising at least one electrode formed from the battery electrode composition of claim 1 . 17. A method of manufacturing a battery electrode composition, comprising: selecting a curvature for a curved geometrical structure of one or more planar substrate backbones based upon a volume expansion characteristic of an active material; providing one or more planar substrate backbones having the curved geometrical structure; at least partially encasing each substrate backbone with a non-porous, continuous or substantially continuous active material film that includes the active material to form one or more composite material nanocomposites having a curved planar geometry, wherein the film has an average thickness on either side of the substrate backbone in the range of 1.4 nm to 200 nm, and wherein the active material stores metal ions within the film and is subject to volume changes greater than about 5% upon insertion or extraction of the metal ions; and aggregating the nanocomposites into a three-dimensional, electrically-interconnected agglomeration that includes internal pores between the nanocomposities that are left vacant and have a total porosity in the three-dimensional agglomeration that is defined by the curvatures of the nanocomposites of the plurality of electrically-interconnected nanocomposites so as to be sufficient to accommodate the volume changes in the active material that are greater than about 5% upon insertion or extraction of the metal. 18. The method of claim 17 , further comprising: at least partially filling the internal pores between the nanocomposites in the agglomeration with a solid electrolyte. 19. The method of claim 17 , wherein the volume changes in the active material that are accommodated by the internal pores range between about 300% and about 400% upon insertion or extraction of the metal ions.