Electrolysis methods that utilize carbon dioxide and a high nickel-content anode for making desired nanocarbon allotropes

We claim: 1. A method for producing a carbon nanomaterial (CNM) product, the method comprising steps of: a. heating an electrolyte media to obtain a molten electrolyte media; b. positioning the molten electrolyte media between a high-nickel content anode and a cathode of an electrolytic cell; c. introducing a source of carbon into the electrolytic cell; d. applying an electric current to the cathode and the anode in the electrolytic cell; and e. collecting the CNM product from the cathode, wherein the CNM product comprises a minimal relative-amount of at least 70 wt %, as compared to a total weight of the CNM product, of a desired allotrope selected from a group of a conical carbon nanofiber, a nano-bamboo, and a nano-tree that comprises a trunk carbon nanotube (CNT) with a plurality of branch CNTs that extend away from the trunk CNT, wherein the high-nickel content anode is made of pure nickel or an alloy that comprises greater than 50 wt % nickel. 2. The method of claim 1 , further comprising a step of adding an iron-containing salt to the electrolyte media or the molten electrolyte media. 3. The method of claim 1 , wherein the high-nickel content anode comprises an alloy comprising at least 50 wt % nickel. 4. The method of claim 1 , wherein the high-nickel content anode is a composite anode comprising a first layer of a first alloy that comprises at least 50 wt % nickel and at least a second layer of a second alloy that comprises at least 50 wt % nickel, and wherein the first alloy and the second alloy are different. 5. The method of claim 1 , wherein the anode and the cathode are both made of pure nickel and the desired allotrope is the nano-bamboo. 6. The method of claim 1 , further comprising a step of adding a nickel-containing additive to the electrolyte media or the molten electrolyte media, relative to an amount of the electrolyte media or the molten electrolyte media, wherein the anode is a composite anode comprising a first layer of a first alloy that comprises at least 50 wt % nickel and at least a second layer of a second alloy that comprises at least 50 wt % nickel, wherein the first alloy and the second alloy are different and wherein the desired allotrope is the nano-bamboo. 7. The method of claim 1 , wherein the molten electrolyte media is freshly melted and the CNM product comprises the conical nanofiber. 8. The method of claim 1 , further comprising a step of adding a nickel-containing additive to the electrolyte media or the molten electrolyte media, wherein the anode is a composite anode comprising a first layer of a first alloy that comprises at least 50 wt % nickel and at least a second layer of a second alloy that comprises at least 50 wt % nickel, wherein the first alloy and the second alloy are different, and wherein the desired allotrope is the nano-bamboo. 9. The method of claim 1 , further comprising a step of introducing a lithium-containing additive into the electrolyte media or the molten electrolyte media, wherein the anode is a composite anode comprising a first layer of a first alloy that comprises at least 50 wt % nickel and at least a second layer of a second alloy that comprises at least 50 wt % nickel, wherein the first alloy and the second alloy are different and wherein the desired allotrope is the nano-tree. 10. The method of claim 9 , wherein the lithium-containing additive is lithium oxide that is added in an amount between about 0.05 wt % and 0.5 wt %, relative to an amount of the electrolyte media or the molten electrolyte media. 11. The method of claim 1 , further comprising a step of introducing a magnetic additive component into the electrolytic cell, wherein the magnetic additive component comprises a magnetic material addition component, a carbide-growth component or any combination thereof and wherein the desired allotrope is magnetic and moves when in a magnetic field. 12. The method of claim 1 , further comprising a step of introducing a doping additive component into the electrolytic cell, wherein the desired allotrope is doped and atoms of the doping additive component are directly incorporated throughout the doped desired allotrope to impart desired physical and/or chemical properties to the doped desired allotrope that are different than an undoped desired allotrope.