Nanofeatured electrodes and energy storage coaxial cables therefrom

The invention claimed is: 1. A method of fabricating electrodes having protruding nanofeatures, comprising: growing metal oxide nanofeatures on a metal or metal alloy wire using a heat treatment in an oxidizing environment; depositing an electrically conducting material on said nanofeatures to form coated nanofeatures, and depositing an electrochemically active material (active material) coating onto said coated nanofeatures to form at least one nanofeatured electrode. 2. The method of claim 1 , wherein said metal or metal alloy wire comprises a copper wire, said metal oxide is copper oxide, said depositing said electrically conducting material comprises sputtering, and wherein said depositing said nanofeatures of said active material comprises electrodepositing. 3. The method of claim 1 , wherein said active material comprises MnO 2 . 4. The method of claim 1 , wherein said at least one nanofeatured electrode comprises a first nanofeatured electrode and a second nanofeatured electrode, wherein said first nanofeatured electrode is configured as a linear electrode and said second nanofeatured electrode is configured as a tubular electrode, and assembling an electrode energy storage coaxial cable (ESCC) by adding an ion porous separator and an electrolyte between said first nanofeatured electrode positioned as an inner electrode for said ESCC and said second nanofeatured electrode positioned as an outer electrode for said ESCC. 5. The method of claim 4 , further comprising forming an outer plastic jacket after said assembling that provides encapsulation for said ESCC. 6. The method of claim 4 , wherein said electrolyte comprises a solid electrolyte. 7. The method of claim 4 , wherein said electrolyte comprises a liquid electrolyte. 8. The method of claim 1 , wherein said electrically conducting material comprises a metal or a metal alloy. 9. A nanofeatured electrode, comprising: an inner metal or metal alloy wire having metal oxide nanowiskers (NWs) protruding from said metal or metal alloy wire; an electrically conducting material on said NWs, and an electrochemically active material (active material) coating on said electrically conducting material. 10. The nanofeatured electrode of claim 9 , wherein said metal or metal alloy wire comprises a copper wire and said metal oxide is copper oxide. 11. The nanofeatured electrode of claim 9 , wherein said active material comprises MnO 2 . 12. The nanofeatured electrode of claim 9 , wherein said electrically conducting material comprises a metal or a metal alloy. 13. An energy storage coaxial cable (ESCC), comprising: a first nanofeatured electrode; and a second nanofeatured electrode; wherein said first nanofeatured electrode is configured as a linear electrode and said second nanofeatured electrode is configured as a tubular electrode, each said first and said second nanofeatured electrode comprising: an inner metal or metal alloy wire having metal oxide nanowiskers (NWs) protruding from said metal or metal alloy wire; an electrically conducting material on said NWs; an electrochemically active material (active material) coating on said electrically conducting material, and an ion porous separator and an electrolyte between said first nanofeatured electrode positioned as an inner electrode for said ESCC and said second nanofeatured electrode positioned as an outer electrode for said ESCC. 14. The ESCC of claim 13 , wherein said metal or metal alloy wire comprises a copper wire and said metal oxide is copper oxide. 15. The ESCC of claim 13 , wherein said active material comprises MnO 2 . 16. The ESCC of claim 13 , further comprising an outer plastic jacket that provides encapsulation for said ESCC. 17. The ESCC of claim 13 , wherein said electrolyte comprises a solid electrolyte. 18. The ESCC of claim 13 , wherein said electrolyte comprises a liquid electrolyte. 19. The ESCC of claim 13 , wherein said electrically conducting material comprises a metal or a metal alloy.