Limits to High Field Magnets for Particle Accelerators

Todesco, E.; Ferracin, P.

doi:10.1109/tasc.2011.2181143

Cited by 14 publications

(9 citation statements)

References 23 publications

(23 reference statements)

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“…Probably it will run at 7.7 T, 20% less than the short sample limit of 9.7 T 2. The overall current density of the coil should be around 400 A/mm 2 , at the design field, as in all previous accelerator magnets [36]. Lower current density means a too large and expensive magnet, higher current density (if available!)…”

Section: Magnets Concept For the He-lhcmentioning

confidence: 99%

Advanced Accelerator Magnets for Upgrading the LHC

Bottura

Rijk

Rossi

et al. 2012

IEEE Trans. Appl. Supercond.

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182

125

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Section: Magnets Concept For the He-lhcmentioning

confidence: 99%

Advanced Accelerator Magnets for Upgrading the LHC

Bottura

Rijk

Rossi

et al. 2012

IEEE Trans. Appl. Supercond.

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182

125

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“…Dipole field in excess of 15-16 T, the Nb3Sn limit [20], is very advantageous if the new machine will be built in the LHC tunnel (HE-LHC), see Fig. 1, given the "limited" circumference of 27 km.…”

Section: A Eucard2-wp10 Programmementioning

confidence: 99%

The EuCARD-2 Future Magnets European Collaboration for Accelerator-Quality HTS Magnets

Rossi

Badel

Bajko

et al. 2015

IEEE Trans. Appl. Supercond.

114

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Abstract-EuCARD-2 is a project supported by FP7-European Commission that includes, inter alia, a work-package (WP10) called "Future Magnets". This project is part of the long term development that CERN is launching to explore magnet technology at 16 T to 20 T dipole operating field, within the scope of a study on Future Circular Colliders. The EuCARD2 collaboration is closely liaising with similar programs for high field accelerator magnets in the USA and Japan. The main focus of EuCARD2 WP10 is the development of a 10 kA-class superconducting, high current density cable suitable for accelerator magnets, The cable will be used to wind a stand-alone magnet 500 mm long and with an aperture of 40 mm. This magnet should yield 5 T, when stand-alone, and will enable to reach a 15 to 18 T dipole field by placing it in a large bore background dipole of 12-15 T. REBCO based Roebel cables is the baseline. Various magnet configurations with HTS tapes are under investigation and also use of Bi-2212 round wire based cables is considered. The paper presents the structure of the collaboration and describes the main choices made in the first year of the program, which has a breadth of five to six years of which four are covered by the FP7 frame.

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“…These large forces require a careful stress management, as the stress limit of Nb 3 Sn magnet coils is nowadays considered to be up to 200 MPa [27]. Also the stored energy (Figure 1, right) will bear large challenges, especially to maintain a hot-spot temperature below 300 K. The copper-to-superconductor ratio has to be selected adequately in order to limit the hot-spot temperature in case of quench.…”

Section: Design Considerationsmentioning

confidence: 99%

Strategy for Superconducting Magnet Development for a Future Hadron-Hadron Circular Collider at CERN

Schoerling¹,

Bajas²,

Bajko³

et al. 2016

Proceedings of the European Physical Society Conference on High Energy Physics — PoS(EPS-HEP2015)

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Following the recommendation of the European Strategy Group for Particle Physics, a study on options for a Future Circular Collider (FCC) with centre-of-mass energy of 100 TeV, a luminosity of 5 − 10 × 10 34 cm 2 s −1 and a circumference in the range of 100 km was started. The study integrates ongoing accelerator and technology initiatives at CERN, Geneva, Switzerland and in partner institutes and universities. A key technology for the FCC are high-field superconducting accelerator magnets. The FCC arc magnets need an aperture of 50 mm, with dipole fields with a target of 16 T and quadrupole gradients with a target in excess of 400 T/m. Based on these preliminary parameters, in this paper we discuss the challenges for the main magnetic elements of such a collider, and outline a strategy for the development of the required technology.

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Limits to High Field Magnets for Particle Accelerators

Cited by 14 publications

References 23 publications

Advanced Accelerator Magnets for Upgrading the LHC

Advanced Accelerator Magnets for Upgrading the LHC

The EuCARD-2 Future Magnets European Collaboration for Accelerator-Quality HTS Magnets

Strategy for Superconducting Magnet Development for a Future Hadron-Hadron Circular Collider at CERN

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