SBIR-STTR Award

The cost of second generation (2G) superconducting coated conductors, needed to expand the nation’s electricity delivery system, largely depends on the ability to manufacture superconducting wire with high throughput. An important parameter that controls throughput is the rate at which superconducting material is deposited in the manufacturing process. Currently, deposition rates remain rather moderate. This project will develop ultra-fast deposition methods for producing high quality films for 2G coated conductors. Phase I will develop an improved method of feeding precursor material, which will allow for enhanced deposition rates of coated conductor material.

Commercial Applications and Other Benefits as described by the awardee:
Ultra-fast deposition methods should facilitate the penetration of 2G coated conductors into broad commercial markets. Large energy savings have been projected from the use of high temperature superconductors for applications as varied as transformers, transmission lines, motors and generators, and magnetic energy storage

One of the major factors that inhibits rapid throughput, and hence increases the cost, of coated conductors is the moderate deposition rate of high temperature superconducting films. Thus far, the approach has been to increase the deposition area using moderately rapid deposition techniques. By developing the industrial methods of ultra-fast deposition to produce coated conductors, the overall production time, and thus overall cost, of second generation coated conductors can be reduced. The Phase I project demonstrated the technical feasibility of the proposed approach. The Phase II effort will implement appropriate enhancement of ultra-fast growth rate continuous deposition, and enable further process scale-up.

Commercial Applications and Other Benefits as described by the awardee:
The ultra-fast deposition of high current carrying capacity superconducting wire will deliver low cost, high performance superconducting wire to commercial markets for integration into motors, transformers, transmission lines, and other devices