creator Trenikhina, Yulia advisor Zasadzinski, John Francis Nano-scale investigation of intrinsic properties of niobium near-surface is a key to control performance of niobium superconducting radio-frequency cavities. Mechanisms responsible for the performance limitations and their empirical remedies needs to be justified in order to reproducibly control fabrication of SRF cavities with desired characteristics. The high field Q-slope and mechanism behind its cure (120◦C mild vacuum bake) were investigated by comparison of the samples cut out of the cavities with high and low dissipation regions. Material evolution during mild field Q-slope nitrogen treatment was characterized using the coupon samples as well as samples cut out of nitrogen treated cavity. Evaluation of niobium near-surface state after some typical and novel cavity treatments was accomplished. Various TEM techniques, SEM, XPS, AES, XRD were used for the structural and chemical characterization of niobium near-surface. Combination of thermometry and structural temperature-dependent comparison of the cavity cutouts with different dissipation characteristics revealed precipitation of niobium hydrides to be the reason for medium and high field Q-slopes. Step-by-step effect of the nitrogen treatment processing on niobium surface was studied by analytical and structural characterization of the cavity cutout and niobium samples, which were subject to the treatment. Low concentration nitrogen doping is proposed to explain the benefit of nitrogen treatment. Chemical characterization of niobium samples before and after various surface processing (Electropolishing (EP), 800◦C bake, hydrofluoric acid (HF) rinsing) showed the differences that can help to reveal the microscopic effects behind these treatments as well as possible sources of surface contamination. Submitted by Erma Thomas (thomase@iit.edu) on 2015-07-20T19:46:32Z No. of bitstreams: 1 Yulia Trenikhina thesis.pdf: 7199781 bytes, checksum: aa38557c066f40149237ce7d20b6ecd0 (MD5) Made available in DSpace on 2015-07-20T19:46:32Z (GMT). No. of bitstreams: 1 Yulia Trenikhina thesis.pdf: 7199781 bytes, checksum: aa38557c066f40149237ce7d20b6ecd0 (MD5) Previous issue date: 2014-12 Ph.D. in Physics, December 2014 2014 2014-12 http://hdl.handle.net/10560/3459 en Dissertation born digital application/pdf In Copyright http://rightsstatements.org/page/InC/1.0/ Restricted Access PHYS / Physics Illinois Institute of Technology Affiliated department