Bernhard Zipfel scite author profile

In the scope of the Facility for Antiproton and Ion Research (FAIR) project, several new synchrotrons and storage rings will be built. The existing heavy-ion synchrotron SIS18 has to be upgraded to serve as an injector for the FAIR accelerators. All this imposes new requirements on the low-level rf (LLRF) systems. These requirements include fast ramping modes, arbitrary ion species, and complex beam manipulations such as dual-harmonic operation, bunch merging/splitting, barrier bucket operation, or bunch compression. In order to fulfill these tasks, a completely new and unique system architecture has been developed since 2002, and the system is now used in SIS18 operation. The presentation of this novel system architecture is the purpose of this paper. We first describe the requirements and the design of the LLRF system. Afterwards, some key components and key interfaces of the system are summarized followed by a discussion of technological aspects. Finally, we present some beam experiment results that were obtained using the new LLRF system.

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A facility for the research, development, and translation of advanced technologies for ion-beam therapies

Lis¹,

Newhauser²,

Donetti³

et al. 2021

J. Inst.

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This article describes the updated GSI radiotherapy research facility (Cave M) located at the GSI Helmholtz Center for Heavy Ion Research in Darmstadt, Germany. This facility was upgraded by modernizing the beamline that supported a pilot project in carbon ion cancer therapy in Europe from 1997 to 2008. Descriptions are provided of the modernized beamline, related hardware components and treatment delivery system. The performance specifications and general characteristics for each major component are described, along with example pre-clinical test results of selected components. These upgrades to Cave M allow for investigating novel therapy methods. The radiotherapy research facility is located on a beamline of the heavy ion synchrotron (Schwer-Ionen-Synchrotron, or SIS-18) accelerator complex, capable of delivering 0.1 to 2 GeV/u charged particle beams, ranging from protons to uranium. This beamline contains components for fast beam gating, aborting, focusing, scanning, monitoring, and shifting the range of the beam. The beam scanning magnets, position detectors, and beam monitors are described, along with tests of functionality and performance. A dose delivery system (DDS) was adapted from a clinical unit at the National Centre for Oncological Hadrontherapy (CNAO), Pavia, Italy, and consists of modular real-time hardware and software. The DDS was modified to enable research on adaptively-managed patient motion through the use of libraries of 4D-optimized radiation treatment plans, an unsolved problem of importance for treating moving tumors. The system is modular and is designed to support future research studies, such as high dose rate (Flash) radiotherapy and radioactive ion beams. A series of validation tests confirmed the functionality and performance of various key components and systems. For example, an end-to-end test revealed that dosimetric spatial homogeneity of over 95% was achieved for square treatment fields. More generally, all performance characteristics that were tested satisfied anticipated clinical requirements.

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A generation of unconventional electron beam ion sources

Kleinod¹,

Becker²,

Bongers³

et al. 1996

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While a high electron current electron beam ion source (EBIS) with high perveance has been proposed for its application at forthcoming TeV hadron colliders, an economical operation has been studied using oscillating electrons to reduce the collector current for low power consumptions. Results with oscillating electrons in our cryogenic EBIS with a 5 T magnetic focusing field are being discussed in relation to normal EBIS operation data considering the oscillation factor, current density, and ion yield. Our simplified EBIS/EBIT studies without magnetic focusing now span from a versatile source for the production of high current singly charged metallic ions up to the use of relativistic electron beams for the production of bare uranium. The XEBIST now works successfully with beam energies up to 10 keV. Barium ions having a charge state up to 46 have been extracted using evaporative cooling by Ar and residual gas. The extension to relativistic beam energies taking advantage of the self-focusing effect at partial space charge compensation will be presented elsewhere at this conference.

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Electron optical imaging properties of the KATRIN high field solenoid chain

Osipowicz

Zipfel

2014

Nuclear Instruments and Methods in Physics Research Section A:

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Bernhard Zipfel

A Digital Beam-Phase Control System for Heavy-Ion Synchrotrons

New digital low-level rf system for heavy-ion synchrotrons

A facility for the research, development, and translation of advanced technologies for ion-beam therapies

A generation of unconventional electron beam ion sources

Electron optical imaging properties of the KATRIN high field solenoid chain

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