Title: Seamless Nb tubes for SRF cavities

A. Executive Summary Understanding Developed Relationships between level of work, plastic strain orientation, level of annealing, grain size, strength, ductility, and texture were developed for heavily worked bulk RRR grade cast pure niobium (Nb). Technical Effectiveness of Approach Part A: The approach used for plastic deformation of bulk Nb was room temperature equal channel angular extrusion (ECAE). This approach is very effective for microstructural breakdown of worked and post-strain recrystallized Nb. A major problem with breaking down the microstructure of cast Nb is development of a consistent (repeatable) and uniform microstructure. This is most effectively accomplished by a series of orthogonal working steps (multipass ECAE (mECAE)) separated by full recrystallization. Forming tube from such material leads to a uniform microstructure in the tube. Part B: The approach developed to produce a microstructure in thin-walled tube that is very favorable for hydroforming into a superconducting radio frequency (SRF) cavity is tube-ECAE (tECAE). Tube-ECAE results in an axisymmetric circumferentially uniform microstructure with a texture more favorable for expansion hydroforming than tube formed by conventional methods such as extrusion, drawing, and ironing. Economic Feasibility of Methods Investigated and Demonstrated Although this was not demonstrated because of funding limitations, it is strongly believed that mECAE combined with intermediate recrystallization heat treatments and tECAE are economically viable approaches for producing a consistent, uniform, fine- or coarse-grained microstructure in RRR grade Nb tube starting from a large-grained and highly textured cast ingot. These methods are relatively easy to apply; the challenge is development of equipment and tooling that works well and is operator friendly. Commercially viable ECAE tooling for bulk Nb microstructure breakdown was developed; significant progress was made on the design of scaled-up equipment for tECAE. Patents on tECAE have been granted in Europe, Japan, and the United States. Public Benefit The approaches developed for fabricating RRR grade Nb tubing suitable for hydroforming into multi-cell SRF cavities have substantial public benefit because they will enable the manufacture of lower cost multicell SRF cavities for advanced linear particle accelerators. In addition, the approach developed for fabricating uniform and consistent axisymmetric microstructures in metal tubing can be applied to tubes made of metal alloys other than Nb. Applications exist in Ta tubing for superconductor wire applications, Mg alloy tubing for bio-implants, and aerospace tubing for structural hollow section components. The idea of tECAE can be applied to heal the heat affected zone (HAZ) in seam-welded tubing, thus erasing or healing the low-strength properties in the weld zone.