Development of sputtered Nb<sub>3</sub>Sn films on copper substrates for superconducting radiofrequency applications

Ilyina, E. A.; Rosaz, G.; Descarrega, Josep Busom; Vollenberg, W.; Lunt, Alexander J.G.; Léaux, F.; Calatroni, S.; Venturini-Delsolaro, W; Taborelli, M.

doi:10.1088/1361-6668/aaf61f

Cited by 33 publications

(24 citation statements)

References 29 publications

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“…The experiments of Nb/Sn multilayers on oxidized Si and sapphire showed that, Nb 6 Sn 5 phase was present during the growth of A15 Nb 3 Sn. The Nb 6 Sn 5 phase disappeared above 800 • C. In this study, the highest T c of 17.45 K was observed for films annealed at 850 • C. Nb 3 Sn sputtered on copper [13,18,19] and Nb [20,21] substrates were studied for its application in SRF cavities. For Nb 3 Sn deposited on copper, the annealing temperature was limited to 830 • C due to a lower melting point of copper and the mismatch between the thermal expansion coefficients of copper and Nb 3 Sn [13].…”

Section: Introductionmentioning

confidence: 82%

“…The Nb 6 Sn 5 phase disappeared above 800 • C. In this study, the highest T c of 17.45 K was observed for films annealed at 850 • C. Nb 3 Sn sputtered on copper [13,18,19] and Nb [20,21] substrates were studied for its application in SRF cavities. For Nb 3 Sn deposited on copper, the annealing temperature was limited to 830 • C due to a lower melting point of copper and the mismatch between the thermal expansion coefficients of copper and Nb 3 Sn [13]. Niobium has a high melting point and a thermal expansion coefficient close to that of Nb 3 Sn [22].…”

Section: Introductionmentioning

confidence: 82%

“…Magnetron sputtering has been used to grow Nb 3 Sn films from a single stoichiometric Nb 3 Sn target [10][11][12][13], using separate Nb and Sn targets to deposit multilayers that are thermally interdiffused [14][15][16], or co-sputtering of Nb and Sn [17]. Early successful fabrication of Nb 3 Sn films by magnetron sputtering from a stoichiometric target was performed at Argonne National Lab [10,11].…”

Section: Introductionmentioning

confidence: 99%

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Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Sayeed

Pudasaini

Reece

et al. 2021

Applied Surface Science

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Superconducting Nb 3 Sn films were fabricated on sapphire and fine grain Nb substrates by magnetron sputtering from a single stoichiometric Nb 3 Sn target. The structural, morphological and superconducting properties of the films annealed for 24 h at temperatures of 800-1000 • C were investigated. The effect of the annealing time at 1000 • C was examined for 1, 12, and 24 h. The film properties were characterized by X-ray diffraction, scanning electron microscopy, atomic force microscopy, energy dispersive X-ray spectroscopy, and Raman spectroscopy. The DC superconducting properties of the films were characterized by a four-point probe measurement down to cryogenic temperatures. The RF surface resistance of films was measured over a temperature range of 6-23 K using a 7.4 GHz sapphire-loaded Nb cavity. As-deposited Nb 3 Sn films on sapphire had a superconducting critical temperature of 17.21 K, which improved to 17.83 K when the film was annealed at 800 • C for 24 h. For the films annealed at 1000 • C, the surface Sn content was reduced to ~11.3% for an annealing time of 12 h and to ~4.1% for an annealing time of 24 h. The Raman spectra of the films confirmed the microstructural evolution after annealing. The RF superconducting critical temperature of the as-deposited Nb 3 Sn films on Nb was 16.02 K, which increased to 17.44 K when the film was annealed at 800 • C for 24 h.

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Section: Introductionmentioning

confidence: 82%

Section: Introductionmentioning

confidence: 82%

Section: Introductionmentioning

confidence: 99%

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Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Sayeed

Pudasaini

Reece

et al. 2021

Applied Surface Science

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“…Among the different intermetallic phases of the Nb-Sn system, only the A15-type Nb 3 Sn is superconducting above 10 K. However, thin film synthesis of high quality Nb 3 Sn is still a huge challenge. 2 Among the reported thin film deposition methods are tin evaporation, [3][4][5] chemical vapor deposition, 6 sputtering, [7][8][9][10][11] electron beam evaporation, 12 bronze processing, 13 and electrodeposition. 14 However, the tin diffusion process is the only process used so far for the production of cavities.…”

Section: Introductionmentioning

confidence: 99%

Kinetically induced low-temperature synthesis of Nb3Sn thin films

Schäfer

Karabas

Palakkal

et al. 2020

Journal of Applied Physics

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Nb 3 Sn thin films are promising candidates for future application in superconducting radio frequency cavities due to their low surface resistivity, high critical temperature, and critical field, as compared to bulk niobium, which is the current state of the art. In this paper, we report the deposition of Nb 3 Sn thin films by magnetron co-sputtering at the extremely low temperature of 435 C. These thin films show a critical temperature of 16.3 K, a high critical current density of 1:60 Â 10 5 A=cm 2 , and a strong shielding effect. The key to achieving low-temperature growth is the independent kinetic control of Nb and Sn species in the sputtering process. From a technological viewpoint, the low-temperature approach paves the way for the use of Nb 3 Sn as a coating in cryogenic efficient copper based cavities, thereby avoiding the detrimental interdiffusion of Cu.

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“…Various technique have been developed to grow Nb 3 Sn superconductor. Bronze routes, sputtering techniques, tin dip et cetera have been studied (see [7][8][9][10] and references therein), but require further development due to the exceptional quality of the RF surface necessary to sustain high RF fields. The best Nb 3 Sn-coated SRF cavities so far have been produced with the so-called vapor diffusion process [11].…”

Section: Introductionmentioning

confidence: 99%

Nb3Sn multicell cavity coating system at JLAB

Eremeev,

Clemens,

Macha

et al. 2020

Preprint

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SRF niobium cavities are the building blocks of modern accelerators for scientific applications. Lower surface resistance, higher fields, and high operating temperatures advance the reach of the future accelerators for scientific discovery as well as potentially enabling cost-effective industrial solutions. We describe the design and performance of an Nb 3 Sn coating system that converts the inner surface of niobium cavities to Nb 3 Sn film. Niobium surface, heated by radiation from the niobium retort, is exposed to Sn and SnCl 2 vapor during the heat cycle, which results in about 2 µm Nb 3 Sn film on the niobium surface. Film composition and structure as well as RF properties with 1-cell R&D cavities and 5-cell practical accelerator cavities are presented.

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Development of sputtered Nb₃Sn films on copper substrates for superconducting radiofrequency applications

Cited by 33 publications

References 29 publications

Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Kinetically induced low-temperature synthesis of Nb3Sn thin films

Nb3Sn multicell cavity coating system at JLAB

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Development of sputtered Nb3Sn films on copper substrates for superconducting radiofrequency applications

Cited by 33 publications

References 29 publications

Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Properties of Nb3Sn films fabricated by magnetron sputtering from a single target

Kinetically induced low-temperature synthesis of Nb3Sn thin films

Nb3Sn multicell cavity coating system at JLAB

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Product

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Development of sputtered Nb₃Sn films on copper substrates for superconducting radiofrequency applications