Add to ORKGDue to its better superconducting properties (critical temperature Tc~ 18.3 K, superheating field Hsh~ 400 mT), Nb3Sn is considered as a potential alternative to niobium (Tc~ 9.25 K, Hsh~ 200 mT) for superconducting radiofrequency (SRF) cavities for particle acceleration. Magnetron sputtering is an effective method to produce superconducting Nb3Sn films. We deposited superconducting Nb3Sn films on samples with magnetron sputtering using co-sputtering, sequential sputtering, and sputtering from a stoichiometric target. Nb3Sn films produced by magnetron sputtering in our previous experiments have achieved DC superconducting critical temperature up to 17.93 K and RF superconducting transition at 17.2 K. A magnetron sputtering system with two i...
Nb3 Sn has the potential to significantly improve cryogenic efficiency and maximum fields in superco...
Abstract Niobium sputtered film microstructure and morphology and consequently its superconducting...
Nb₃Sn is a next-generation superconducting material that can be used for future superconducting radi...
Due to its better superconducting properties (critical temperature Tc~ 18.3 K, superheating field Hs...
Particle accelerators are considered as an important device that has wide applications in cancer tre...
Nb3Sn is considered as an alternative of Nb for SRF accelerator cavity application due to its potent...
Superconducting radiofrequency (SRF) cavities that could provide a higher quality factor as well as ...
Nb₃Sn thin films are promising candidates for future application in superconducting radio frequency ...
The production of superconducting coatings for radio frequency cavities is a rapidly developing fiel...
The performance of the Nb bulk cavities has now reached the theoretical limits imposed by the materi...
Superconducting radio-frequency (SRF) resonator cavities provide extremely high quality factors \u3e...
In the modern SRF research, Thin films coated niobium cavities are used for the low cost and increas...
Cost and energy savings are an integral requirement in the design of future particle accelerators. V...
Nb3Sn thin films are promising candidates for future application in superconducting radio frequency ...
The deposition of superconducting Nb3 Sn on copper accelerating cavities is interesting for the high...
Nb3 Sn has the potential to significantly improve cryogenic efficiency and maximum fields in superco...
Abstract Niobium sputtered film microstructure and morphology and consequently its superconducting...
Nb₃Sn is a next-generation superconducting material that can be used for future superconducting radi...
Due to its better superconducting properties (critical temperature Tc~ 18.3 K, superheating field Hs...
Particle accelerators are considered as an important device that has wide applications in cancer tre...
Nb3Sn is considered as an alternative of Nb for SRF accelerator cavity application due to its potent...
Superconducting radiofrequency (SRF) cavities that could provide a higher quality factor as well as ...
Nb₃Sn thin films are promising candidates for future application in superconducting radio frequency ...
The production of superconducting coatings for radio frequency cavities is a rapidly developing fiel...
The performance of the Nb bulk cavities has now reached the theoretical limits imposed by the materi...
Superconducting radio-frequency (SRF) resonator cavities provide extremely high quality factors \u3e...
In the modern SRF research, Thin films coated niobium cavities are used for the low cost and increas...
Cost and energy savings are an integral requirement in the design of future particle accelerators. V...
Nb3Sn thin films are promising candidates for future application in superconducting radio frequency ...
The deposition of superconducting Nb3 Sn on copper accelerating cavities is interesting for the high...
Nb3 Sn has the potential to significantly improve cryogenic efficiency and maximum fields in superco...
Abstract Niobium sputtered film microstructure and morphology and consequently its superconducting...
Nb₃Sn is a next-generation superconducting material that can be used for future superconducting radi...