TRADING STUDIES OF A VERY LARGE HADRON COLLIDER
The authors have shown that the design of the ELOISATRON can be approached in five separate steps. In this report they deal with the two major issues of the collider: the size and the strength of the superconducting magnets. The reference design of the SSC calls for a collider circumference of 86 km. It represents the largest size that until recently was judged feasible. The reference design of the LHC requires a bending field of 9 Tesla, that industries are presently determined to demonstrate. Clearly the large size of the project presents problem with magnet tolerances, and collider operation and management. The high field of the superconducting magnets needs to be demonstrated, and the high-field option in excess of 9 Tesla requires extensive research and development. It is obvious from the start that, if the ELOISATRON has to allow large beam energies, the circumference has also to be larger than that of the SSC, probably of few hundred kilometers. On the other end, Tevatron, RHIC and SSC type of superconducting magnets have been built and demonstrated on a large scale and proven to be cost effective and reliable. Their field, nevertheless, hardly can exceed a value of 7.5 Tesla, without major modifications that need to be studied. The LHC type of magnets may be capable of 9 Tesla, but they are being investigated presently by the European industries. It is desired that if one wants to keep the size of the ring under reasonable limits, a somewhat higher bending field is required for the ELOISATRON, especially if one wants also to take advantage of the synchrotron radiation effects. A field value of 13 Tesla, twice the value of the SSC superconducting magnets, has recently been proposed, but it clearly needs a robust program of research and development. This magnet will not probably be of the RHIC/SSC type and not even of the LHC type. It will have to be designed and conceived anew. In the following they examine two possible approaches. In the first approach, they take as a starting reference the SSC design with a constant circumference of 87 km. They investigate the energy range of 20 to 100 TeV, and include the synchrotron radiation effects. The required bending field will be calculated accordingly. In the second approach they follow the same as outlined in the first one, except that they assume a constant bending field of 13 Tesla. The circumference of the collider will then be determined accordingly. This study will show the consequences of these assumptions and approaches. In their opinion, the feasibility of the ELOISATRON need control of the overall size at one end, and a bending field which is larger than what has been demonstrated recently.
- Research Organization:
- Brookhaven National Lab. (BNL), Upton, NY (United States)
- Sponsoring Organization:
- USDOE Office of Energy Research (ER) (US)
- DOE Contract Number:
- AC02-98CH10886
- OSTI ID:
- 757105
- Report Number(s):
- BNL-65566; KA0403; R&D Project: AD4ADRD; KA0403; TRN: US0005143
- Resource Relation:
- Conference: HADRON COLLIDERS AT THE HIGHEST ENERGY AND LUMINOSITY, ERICE (IT), 11/04/1996--11/13/1996; Other Information: PBD: 4 Nov 1996
- Country of Publication:
- United States
- Language:
- English
Similar Records
Conclusions of the workshop
Superconducting Magnet Technology for Future Hadron Colliders