[1] C.Z. Antoine, “R&D in superconducting RF: thin film capabilities as a game changer for future sustainability”, in 14th International Particle Accelerator Conference. 2023, JACoW: Venice, Italy. p. 21-26.
[2] R. Valizadeh, et al., “Synthesis of Nb and Alternative Superconducting Film to Nb for SRF Cavity as Single Layer”, in SRF2021. 2022, JACoW Publishing: Geneva, Switzerland. p. 893-898.
[3] A. Sezgin, et al., “The Investigation of Sputtered S (I) S Structures for SRF Cavities”, TFSRF2022, Editor. 2022.
[4] A. Ramiere, C.Z. Antoine, and J. Amrit, “Model for hot spots and Q-slope behavior in granular niobium thin film superconducting rf cavities”. PRAB, 2022. 25(2): p. 022001.
[5] C. Antoine, et al., “Thin films activities in the IFAST program”, in eeFACT2022. 2022, JACoW Publishing: Frascati, Italy. p. 159.
[6] X.J. A.Ö. Sezgin, M. Vogel, R. Ries, E. Seiler, D. Tikhonov, S. Keckert, J. Knobloch, O. Kugeler, L. Smith, O. B. Malyshev, C. Z. Antoine, “Investigation of HIPIMS-coated s(i)s structures for srf cavities”, in LINAC 2022. 2022, Jacow: Liverpool, UK.
[7] D.A. Turner, et al., “A facility for the characterisation of planar multilayer structures with preliminary niobium results”. Superconductor Science and Technology, 2022. 35(9): p. 095004.
[8] O. Hryhorenko, et al., “Exploring innovative pathway for SRF cavity fabrication”, in SRF 2023. 2023.
[9] C. Pira, et al., “Progress in european thin film activities”, in SRF 2023. 2023: Grand Rapids, MI, USA.
[10] M. Arzeo, et al., “Enhanced radio-frequency performance of niobium films on copper substrates deposited by high power impulse magnetron sputtering”. Superconductor Science and Technology, 2022. 35(5): p. 054008.
[11] D. Fonnesu, et al., “Reverse coating technique for the production of Nb thin films on copper for superconducting radio-frequency applications”. Superconductor Science and Technology, 2022.
[12] W. Venturini Delsolaro, et al., “Progress and R/D challenges for FCC-ee SRF”. EPJ Techniques and Instrumentation, 2023. 10(1): p. 1-13.
[13] R.K. S. Keckert, J. Knobloch, F. Kramer, O. Kugeler, D.B. Tikhonov, W. Ackermann, H. De Gersem, X. Jiang, A.O. Sezgin, M. Vogel, M. Wenskat. “Mitigation of Parasitic Losses in the Quadrupole Resonator Enabling Direct Measurements of Low Residual Resistances of SRF Samples”. in 13th International Particle Accelerator Conference. 2022. Bangkok, Thailand.
[14] A. Sezgin, et al. “HiPIMS-coated novel S (I) S multilayers for srf cavities”. in Proc. 31st Int. Particle Accelerator Conf.(IPAC22), Bangkok, Thailand. 2022.
[15] A. Sezgin, et al. “Investigation of HiPIMS-coated S (I) S structures for srf cavities”. in Proc. 31st Int. Linear Accelerator Conf.(LINAC22), Liverpool, UK. 2022.
[16] A.O. Sezgin, et al. “HiPIMS-Coated Novel S(I)S Multilayers for SRF Cavities”. in 13th International Particle Accelerator Conference. 2022. Bangkok, Thailand.
[17] O. Hryhorenko, et al., “Recent advances in metallographic polishing for SRF application”, in arXiv preprint arXiv:2307.03272. 2023.
[18] X.J. M. Vogel, A.O. Sezgin. “New Sputtering Coating Facility for Nb-Based Thin Films in 1.3 GHz Cavities”. in 13th International Particle Accelerator Conference. 2022. Bangkok, Thailand.
[19] M. Wenskat, et al., “Successful Al2O3 coating of superconducting niobium cavities with thermal ALD”. Superconductor Science and Technology, 2022. 36(1): p. 015010.
[20] Y. Kalboussi, et al., “Surface engineering by ALD for superconducting RF cavities”, in SRF2023. 2023.
[21] A.- M. Valente-Feliciano, et al., “Next-Generation Superconducting RF Technology based on Advanced Thin Film Technologies and Innovative Materials for Accelerator Enhanced Performance & Energy Reach”, in Letter of interest Snowmass 21. 2021.
[22] N. Leicester, et al. “Development and Testing of Split 6 GHz cavities with Niobium coatings”. in SRF 2023. 2023: SRF.
[23] G.B. D.A. Turner, O.B. Malyshev, R. Valizadeh, G. Burt, E. Chyhyrynets, C. Pira, T. Junginger, S.B. Leith, M. Vogel, O.B. Malyshev, R. Valizadeh, A. Medvids, R. Ries, E. Seiler, A. Sublet, J.T.G. Wilson, “Magnetic Field Penetration of Niobium Thin Films Produced by the Aries Collaboration”, in SRF2021. 2021: East Lansing, MI, USA.
[24] R. Ries, et al., “Surface quality characterization of thin Nb films for superconducting radiofrequency cavities”. Superconductor Science and Technology, 2022. 35(7): p. 075010.
[25] R. Ries, et al., “Numerical Calculation of Magnetic Field Enhancement and Impact of Surface Defects on Premature Entry of Magnetic Field in Thin Nb Films for SRF Cavities”. IEEE Transactions on Applied Superconductivity, 2023. 33(5): p. 1-5.
[26] D.A. Turner, et al., “Investigating the superconducting properties and surface morphology of sputtered nb films on cu due to laser treatment”. IEEE Transactions on Applied Superconductivity, 2023. 33(4): p. 1-12.
[27] A. Hannah, et al., “First 6 ghz cavity deposition with b1 superconducting thin film at ASTEC”. Proc. IPAC’22, 2022.
[28] V. Candela, et al., “Smoothening of the down-skin regions of copper components produced via Laser Powder Bed Fusion technology”. The International Journal of Advanced Manufacturing Technology, 2022. 123(9): p. 3205-3221.
[29] D. Ford, et al. “Study and Improvements of Liquid Tin Diffusion Process to Synthesize Nb₃Sn Cylindrical Targets”. in 21th International Conference on RF Superconductivity (SRF’23), Grand Rapids, MI, USA, 25-30 June 2023. 2023: JACOW Publishing, Geneva, Switzerland.
[30] G. Ghigo, et al., “Vortex-induced nonlinearity and the effects of ion irradiation on the high-frequency response of NbTi films”. Results in Physics, 2024: p. 107437.
[31] P. Dhakal, T. Tajima, and M. Wenskat, “Progress on superconducting materials for SRF applications”. 2024, Frontiers Media SA. p. 1403513.
[32] G.K. Deyu, et al., “Reducing the Thermal Effects during Coating of Superconducting Radio-Frequency Cavities: A Case Study for Atomic Layer Deposition of Alumina with a Combined Numerical and Experimental Approach”. Chemistry of Materials, 2024. 36(6): p. 2846-2856.
[33] I. González Díaz-Palacio, et al., “Thermal annealing of superconducting niobium titanium nitride thin films deposited by plasma-enhanced atomic layer deposition”. Journal of Applied Physics, 2023. 134(3).
[34] M. Wenskat, et al., “Vacancy dynamics in niobium and its native oxides and their potential implications for quantum computing and superconducting accelerators”. Physical Review B, 2022. 106(9): p. 094516.
[35] D. Fonnesu, et al., “CERN Based $ T_ {c} $ Measurement Station for Thin-Film Coated Copper Samples and Results on Related Studies”. JACoW SRF, 2022. 2021: p. 105-108.
[36] L. Vega Cid, et al., ” Seamless 1.3 GHz Copper Cavities for Nb Coatings: Cold Test Results of Two Different Approaches”. JACoW SRF, 2021. 2021: p. 498-502.
[37] G. Rosaz, et al., “Niobium thin film thickness profile tailoring on complex shape substrates using unbalanced biased High Power Impulse Magnetron Sputtering”. Surface and Coatings Technology, 2022. 436: p. 128306.
[38] G. Eremeev, et al., “submitter: First measurements of HiPIMS Nb film-coated 3D cavity at 1.3 GHz down to 40 mK”. 2022.
[39] A. Bianchi, G. Vandoni, and W.V. Delsolaro, “Temperature measurement on copper surfaces for superconducting thin film cavity applications”. Measurement Science and Technology, 2023. 35(1): p. 015901.
[40] R. Ghanbari, et al., “SURFACE CHARACTERIZATION OF MID-T HEAT TREATED Nb SAMPLES TO INVESTIGATE THE ORIGIN OF RESIDUAL RESISTANCE”.
[41] F. Peauger, et al., “JACOW: SWELL and Other SRF Split Cavity Development”. JACoW LINAC, 2022. 2022: p. 300-304.
[42] A. Bianchi and W. Venturini Delsolaro, “Temperature mapping on a niobium-coated copper superconducting radio-frequency cavity”. Scientific Reports, 2023. 13(1): p. 17075.
[43] I.G. Díaz-Palacio, et al., “Peald sis studies for srf cavities”. Proc. IPAC’22, 2022: p. 1222-1225.