Status of the fair SIS100/300 synchrotron design

Spiller, P.; Blell, U.; Eickhoff, H.; Floch, E.; Fischer, Egbert; Hülsmann, P.; Kaugerts, J.; Kauschke, M.; Klingbeil, Harald; König, H; Krämer, A.; Kramer, Dieter; Laier, Ulrich; Moritz, G.; Omet, C.; Pyka, N.; Ramakers, H.; Reich‐Sprenger, H.; Schwickert, Marcus; Stadlmann, J.; Welker, H.; Kovalenko, A. D.

doi:10.1109/pac.2007.4440775

“…High ramp rates at lower fields are sometimes required for a particular application. Although the ideal operating mode for superconducting magnets is steady state, considerations of operating cost have also driven a growing interest for their use in the case of large installations, such as the Nuclotron (in operation since 1994) at the Joint Institute for Nuclear Research (JINR, Russia) [58] and the Facility for Antiproton and Ion Research (FAIR) under construction at GSI in Darmstadt (DE) [59]. The main challenge for fast cycled accelerator magnets is to achieve the desired field at the specified repetition rate, economically and reliably.…”

Section: ) Magnets For Rapid Cycled Synchrotronsmentioning

confidence: 99%

Superconducting Magnets for Particle Accelerators

Rossi

¹

,

Bottura

²

2013

Reviews of Accelerator Science and Technology

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Superconductivity has been the most influential technology in the field of accelerators in the last 30 years. Since the commissioning of the Tevatron, which demonstrated the use and operability of superconductivity on a large scale, superconducting magnets and rf cavities have been at the heart of all new large accelerators. Superconducting magnets have been the invariable choice for large colliders, as well as cyclotrons and large synchrotrons. In spite of the long history of success, superconductivity remains a difficult technology, requires adequate R&D and suitable preparation, and has a relatively high cost. Hence, it is not surprising that the development has also been marked by a few setbacks.This article is a review of the main superconducting accelerator magnet projects; it highlights the main characteristics and main achievements, and gives a perspective on the development of superconducting magnets for the future generation of very high energy colliders.To be published in Reviews of Accelerator Science and Technology, Vol. 5Geneva, Switzerland CERN-ATS-2013-019February 2013 Superconductivity has been the most influential technology in the field of accelerators in the last 30 years. Since the commissioning of the Tevatron, which demonstrated the use and operability of superconductivity on a large scale, superconducting magnets and rf cavities have been at the heart of all new large accelerators. Superconducting magnets have been the invariable choice for large colliders, as well as cyclotrons and large synchrotrons. In spite of the long history of success, superconductivity remains a difficult technology, requires adequate R&D and suitable preparation, and has a relatively high cost. Hence, it is not surprising that the development has also been marked by a few setbacks. This article is a review of the main superconducting accelerator magnet projects; it highlights the main characteristics and main achievements, and gives a perspective on the development of superconducting magnets for the future generation of very high energy colliders.

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“…An impulse to this line of research was given recently by the German laboratory GSI in Darmstadt, which is pursuing the construction of a new Facility for Antiprotons and Ion Research (FAIR) [46]. The central part of this complex is the two rings SIS100 and SIS300, which will be built in the same tunnel and will have magnetic rigidity B ρ = 100 Tm and B ρ = 300 Tm, respectively.…”

Section: • Quench Detection and Protection Protection Ofmentioning

confidence: 99%

Superconducting Magnets for Particle Accelerators

Rossi

¹

,

Bottura

²

2012

Rev. Accl. Sci. Tech.

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Superconductivity has been the most influential technology in the field of accelerators in the last 30 years. Since the commissioning of the Tevatron, which demonstrated the use and operability of superconductivity on a large scale, superconducting magnets and rf cavities have been at the heart of all new large accelerators. Superconducting magnets have been the invariable choice for large colliders, as well as cyclotrons and large synchrotrons. In spite of the long history of success, superconductivity remains a difficult technology, requires adequate R&D and suitable preparation, and has a relatively high cost. Hence, it is not surprising that the development has also been marked by a few setbacks.This article is a review of the main superconducting accelerator magnet projects; it highlights the main characteristics and main achievements, and gives a perspective on the development of superconducting magnets for the future generation of very high energy colliders.To be published in Reviews of Accelerator Science and Technology, Vol. 5Geneva, Switzerland CERN-ATS-2013-019February 2013 Superconductivity has been the most influential technology in the field of accelerators in the last 30 years. Since the commissioning of the Tevatron, which demonstrated the use and operability of superconductivity on a large scale, superconducting magnets and rf cavities have been at the heart of all new large accelerators. Superconducting magnets have been the invariable choice for large colliders, as well as cyclotrons and large synchrotrons. In spite of the long history of success, superconductivity remains a difficult technology, requires adequate R&D and suitable preparation, and has a relatively high cost. Hence, it is not surprising that the development has also been marked by a few setbacks. This article is a review of the main superconducting accelerator magnet projects; it highlights the main characteristics and main achievements, and gives a perspective on the development of superconducting magnets for the future generation of very high energy colliders.

show abstract

“…Distributed testing infrastructure facilities have been established to assess the different types of superconducting magnets for FAIR in addition to GSI, at JINR/Dubna, at CERN and at INFN/ Salerno. Since the FAIR accelerators are served by the existing accelerators of GSI, the heavy ion linac UNILAC and the heavy ion synchrotron SIS18 are being upgraded [16], for operation as injectors and boosters, concurrently to the on-going FAIR construction. At the time of writing, the reference project schedule forecasts the first beams available in 2025, after completing the commissioning plans of the various beam line sections.…”

Section: Hesrmentioning

confidence: 99%

FAIR status and the PANDA experiment

Belias¹

2020

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The international accelerator Facility for Antiproton and Ion Research in Europe (FAIR) is the next generation accelerator complex for fundamental and applied research with antiproton and ion beams. FAIR will provide worldwide unique facilities enabling a wide spectrum of unprecedented forefront research in hadron and nuclear physics, in atomic physics and nuclear astrophysics as well as in applied sciences like materials research, plasma physics and radiation biophysics. Key features of FAIR are intense beams of antiprotons and ions up to the heaviest and even exotic nuclei covering an energy range from rest up to 30 GeV/u. We present a brief overview on the current construction status of the FAIR accelerator facilities and the associated research pillars with emphasis on PANDA . PANDA (antiProton Annihilation in Darmstadt), is the central experiment to fully exploit the physics research potential of the High Energy Storage Ring (HESR) with intense, phase-space cooled, antiprotons up to 15 GeV/c impinging on a variety of fixed targets. The PANDA detector features two spectrometers, the Target Spectrometer with a SC solenoid magnet of 2 T and the Forward Spectrometer with a 2 Tm dipole magnet. In both spectrometers the PANDA collaboration employs a multitude of modern detector technologies to provide tracking, particle identification, calorimetry and muon identification, arranged hermetically close to 4π around the interaction region with additional detectors for coverage of the forward boosted particles. Focusing on the various PANDA detector systems we present an overview of recent developments, the detector construction progress and conclude with an outline for a phased deployment of PANDA at FAIR.

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Status of the fair SIS100/300 synchrotron design

Cited by 7 publications

References 1 publication

Superconducting Magnets for Particle Accelerators

Superconducting Magnets for Particle Accelerators

Superconducting Magnets for Particle Accelerators

FAIR status and the PANDA experiment

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