Methods and Systems for Fabricating High Quality Superconducting Tapes

What is claimed is: 1 . A superconductor tape prepared by metal organic chemical vapor deposition, the superconductor tape comprising a film thickness greater than approximately 1.5 μm and a critical current density greater than approximately 4 MA/cm 2 at 77 K in a zero applied magnetic field. 2 . The superconductor tape of claim 1 , wherein the superconductor tape is a REBCO film. 3 . The superconductor tape or claim 2 , wherein the REBCO film comprises the formula REBa 2 Cu 3 O 7 . 4 . The superconductor tape of claim 1 , wherein the superconductor tape is substantially uniform. 5 . The superconductor tape of claim 1 , wherein the superconductor tape comprises no observable misoriented grain growth. 6 . A superconductor tape prepared by metal organic chemical vapor deposition, the superconductor tape comprising a film thickness greater than approximately 2 μm and non c-axis grain orientation less than approximately 10%. 7 . The superconductor tape of claim 6 , wherein the superconductor tape is a REBCO film. 8 . The superconductor tape or claim 7 , wherein the REBCO film comprises the formula REBa 2 Cu 3 O 7 . 9 . The superconductor tape of claim 6 , wherein the superconductor tape is substantially uniform. 10 . A superconductor tape prepared by metal organic chemical vapor deposition, the superconductor tape comprising a precursor to film conversion efficiency greater than approximately 20% of theoretical value. 11 . The superconductor tape of claim 10 , wherein the superconductor tape is a REBCO film. 12 . The superconductor tape or claim 11 , wherein the REBCO film comprises the formula REBa 2 Cu 3 O 7 . 13 . The superconductor tape of claim 10 , wherein the superconductor tape is substantially uniform. 14 . The superconductor tape of claim 10 , wherein the superconductor tape comprises no observable misoriented grain growth. 15 . A superconductor tape prepared by a metal organic chemical vapor deposition process comprising the steps of: preheating a superconductor substrate tape with a first roller and a second roller; delivering the pre-heated superconductor substrate tape to a groove in a housing via the first roller and the second roller, wherein the groove is in fluid communication with a chamber; and flowing superconductor precursors in a gas phase through the chamber, wherein the precursors are deposited on the superconductor substrate tape by thermally-activated reaction. 16 . The superconductor of claim 16 , further prepared by a metal organic chemical vapor deposition process comprising the steps of: pre-heating the superconductor substrate tape via Ohmic heating. 17 . The superconductor of claim 15 , further prepared by a metal organic chemical vapor deposition process comprising the steps of: sending, via one or more temperature monitoring devices positioned in optical communication with the tape in the groove, temperature readings to a controller than controls the electric power to the first roller and the second roller in a closed loop to maintain the superconductor substrate tape at a constant temperature. 18 . The superconductor of claim 15 , further prepared by a metal organic chemical vapor deposition process comprising the steps of: flowing the gas phase in a direction of flow that is at least one of parallel to a surface of the superconductor substrate tape and perpendicular to the long axis of the superconductor substrate tape. 19 . The superconductor of claim 15 , further prepared by a metal organic chemical vapor deposition process comprising the steps of: vaporizing the precursors from a liquid to a gas before flowing the gas phase through the chamber. 20 . The superconductor of claim 15 , further prepared by a metal organic chemical vapor deposition process comprising the steps of: heating the chamber to a temperature between approximately 250° C. and approximately 300° C.