Add to ORKGSuperconducting cavities made by sputter-deposition of a thin niobium film onto copper have proven over the years to be a viable alternative to bulk niobium, the best example being the very successful operation of LEP at 200 GeV. It will be shown that this technology, investigated at 1.5 GHz by a dedicated R&D effort at CERN, can be developed to unprecedented performance, proving that no fundamental limitation prevents high quality factors to be maintained over a broad range of accelerating field
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
In order to increase the maximum accelerating gradient in superconducting niobium cavities, electrol...
Studies at CERN on niobium-coated 1.5 GHz superconducting cavities are aimed at understanding and po...
Many laboratories around the world, notably CEBAF, CERN, DESY and KEK, after a period of research an...
Evidence is presented for niobium film cavities performing as well as niobium bulk cavities, at vari...
Superconducting radiofrequency resonators for particle acceleration have become a standard component...
For the energy upgrade of the Large Electron Positron Collider at CERN 216 RF superconducting caviti...
One of the main challenges in the construction of new particles accelerators and the upgrading of th...
CERN has designed and prepared new facilities for the surface treatment and niobium sputter coating ...
An accelerating cavity from LEP. This could be cut open to show the layer of niobium on the inside. ...
Copper cavities with a thin niobium film as used in the large electron positron collider LEP would b...
The surface resistance Rs of superconducting cavities prepared by sputter coating a thin niobium fil...
The niobium/copper (Nb/Cu) sputter technology, successfully used on a large scale for LEP2, has been...
The successful operation of LEP2 has demonstrated the feasibility of using on a large scale copper a...
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
In order to increase the maximum accelerating gradient in superconducting niobium cavities, electrol...
Studies at CERN on niobium-coated 1.5 GHz superconducting cavities are aimed at understanding and po...
Many laboratories around the world, notably CEBAF, CERN, DESY and KEK, after a period of research an...
Evidence is presented for niobium film cavities performing as well as niobium bulk cavities, at vari...
Superconducting radiofrequency resonators for particle acceleration have become a standard component...
For the energy upgrade of the Large Electron Positron Collider at CERN 216 RF superconducting caviti...
One of the main challenges in the construction of new particles accelerators and the upgrading of th...
CERN has designed and prepared new facilities for the surface treatment and niobium sputter coating ...
An accelerating cavity from LEP. This could be cut open to show the layer of niobium on the inside. ...
Copper cavities with a thin niobium film as used in the large electron positron collider LEP would b...
The surface resistance Rs of superconducting cavities prepared by sputter coating a thin niobium fil...
The niobium/copper (Nb/Cu) sputter technology, successfully used on a large scale for LEP2, has been...
The successful operation of LEP2 has demonstrated the feasibility of using on a large scale copper a...
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
Since the late ’80s, CERN has pioneered the development of niobium thin film radio-frequency (RF) ca...
In order to increase the maximum accelerating gradient in superconducting niobium cavities, electrol...