Method and systems for forming carbon nanotubes

What is claimed is: 1. A system for the production of carbon nanotubes, comprising: a feed gas heater comprising a heat exchanger configured to heat a feed gas with waste heat from a waste gas stream; a reactor configured to receive the feed gas from the feed gas heater and to form carbon nanotubes from the feed gas on catalyst in a Bosch reaction, and to discharge a reactor effluent stream, wherein the reactor is a fluidized bed reactor; a separator configured to separate the carbon nanotubes from the reactor effluent stream, forming the waste gas stream; and a water removal system comprising an ambient temperature heat exchanger and a separation vessel, the water removal system configured to separate a bulk of water from the waste gas stream to form a dry waste gas stream. 2. The system of claim 1 , wherein the ambient temperature heat exchanger comprises a water chiller. 3. The system of claim 1 , wherein the ambient temperature heat exchanger comprises an air cooled heat exchanger. 4. The system of claim 1 , comprising a package heater configured to heat the feed gas during startup of the system. 5. The system of claim 1 , comprising: a compressor configured to increase the pressure of the dry waste gas stream; and a final water removal system configured to remove water from the dry waste gas stream. 6. A system for the production of carbon nanotubes, comprising: a feed gas heater comprising a heat exchanger configured to heat a feed gas with waste heat from a waste gas stream; a reactor configured to receive the feed gas from the feed gas heater and to form carbon nanotubes from the feed gas on catalyst in a Bosch reaction, and to discharge a reactor effluent stream; a separator configured to separate the carbon nanotubes from the reactor effluent stream, forming the waste gas stream; a water removal system comprising an ambient temperature heat exchanger and a separation vessel, the water removal system configured to separate a bulk of water from the waste gas stream to form a dry waste gas stream; a compressor configured to increase the pressure of the dry waste gas stream; a final water removal system configured to remove water from the dry waste gas stream; and a gas fractionation system configured to separate a methane rich stream and a CO 2 rich stream from the dry waste gas stream. 7. The system of claim 6 , comprising a mixing system configured to mix the methane rich stream into the feed gas before the feed gas heater. 8. The system of claim 7 , wherein the catalyst comprises metal shot-blasting beads, and wherein the mixing system comprises a static mixer. 9. The system of claim 1 , wherein the catalyst comprises metal beads comprising iron and nickel, or chromium, or any combinations thereof. 10. The system of claim 1 , wherein the catalyst comprises metal beads between about 25 mesh and 50 mesh in size. 11. The system of claim 1 , wherein the reactor is lined with a material configured to prevent degradation of a metal shell of the reactor, and wherein the heat exchanger comprises a shell-and-tube heat exchanger. 12. The system of claim 1 , wherein a piping connection between the reactor and a cross heat exchanger is lined with a refractory material configured to protect a metal surface from degradation. 13. A reaction system for forming carbon nanotubes, comprising: two or more reactors each configured to form carbon nanotubes from feed gas on a catalyst in a Bosch reaction, wherein effluent from each reactor, before a final reactor of the two or more reactors, is feed gas for a downstream reactor, and wherein effluent from the final reactor comprises a reactant depleted waste stream; a respective separation system associated with and downstream of each reactor of the two or more reactors, wherein each separation system is configured to remove carbon nanotubes from the effluent from the associated reactor; a respective feed heater downstream of each separation system, wherein each feed heater comprises a heat exchanger configured to heat feed gas for a following reactor with waste heat from the effluent, and wherein the feed heater downstream of the final reactor is configured to heat feed gas for a first reactor of the two or more reactors; a respective ambient temperature heat exchanger downstream of each feed heater, wherein each ambient temperature heat exchanger is configured to remove water from the effluent; a compressor configured to increase the pressure of the reactant depleted waste stream; another ambient temperature heat exchanger downstream of the compressor, configured to remove water from the reactant depleted waste stream; a gas fractionation system configured to separate the reactant depleted waste stream into a methane enriched stream and a carbon dioxide enriched stream; and a mixer configured to blend the methane enriched stream or the carbon dioxide enriched stream into an initial feed stream to give the feed gas for the first reactor. 14. The reaction system of claim 13 , wherein the two or more reactors each comprise a fluidized bed reactor, and wherein the catalyst comprises metal beads. 15. The reaction system of claim 13 , comprising a respective separation vessel downstream of each ambient temperature heat exchanger, wherein each separation vessel is configured to separate liquid water from gas. 16. The reaction system of claim 13 , comprising package heaters configured to heat the feed gas to each of the two or more reactors, respectively, during startup of the reaction system. 17. The reaction system of claim 16 , wherein the package heaters are a heater configured to be field erected, or is an electric power heater, or a combination thereof. 18. The reaction system of claim 13 , wherein the mixer comprises a static mixer. 19. A system for the production of carbon nanotubes, comprising: a heat exchanger to cross-exchange a feed gas with a waste gas stream to heat the feed gas, wherein the heat exchanger comprises a shell-and-tube heat exchanger; a reactor to receive the feed gas from the heat exchanger and to form carbon nanotubes from the feed gas in a Bosch reaction; a separator to separate the carbon nanotubes from an effluent stream of the reactor, forming the waste gas stream; and a water removal system comprising an ambient temperature heat exchanger and a separation vessel, the water removal system to separate a bulk of water from the waste gas stream to form a dry waste gas stream. 20. A system for the production of carbon nanotubes, comprising: a heat exchanger to cross-exchange a feed gas with a waste gas stream to heat the feed gas; a reactor to receive the feed gas from the heat exchanger and to form carbon nanotubes from the feed gas in a Bosch reaction; a separator to separate the carbon nanotubes from an effluent stream of the reactor, forming the waste gas stream; a water removal system comprising an ambient temperature heat exchanger and a separation vessel, the water removal system to separate a bulk of water from the waste gas stream to form a dry waste gas stream; a compressor to increase pressure of the dry waste gas stream; and a final water removal system to remove water from the dry waste gas stream downstream of the compressor. 21. The system of claim 20 , comprising a gas fractionation system to process the dry waste gas stream downstream of the final water removal system to discharge a methane rich stream and a carbon dioxide rich stream. 22. The system of claim 21