2019
DOI: 10.1103/physrevaccelbeams.22.091601
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Emittance reduction with variable bending magnet strengths: Analytical optics considerations and application to the Compact Linear Collider damping ring design

Abstract: One of the main challenges of the lattice design of e + e − synchrotrons, used as light sources or damping rings, is the minimization of the emittance. The optimal configurations for achieving the absolute minimum emittance are the theoretical minimum emittance (TME) cells. This paper elaborates the optimization strategy in order to further reduce the betatron emittance of a TME cell by using dipoles whose magnetic field varies longitudinally. Based on the analytical results, the magnet design for the fabricat… Show more

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Cited by 10 publications
(6 citation statements)
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“…However, the CLIC prototype is more challenging, as it is a tuneable permanent magnet combining dipole and quadrupole components, with a very high field of 2.3 T at its centre. A recent prototype has been built by CIEMAT as part of the EuCard2 program [69]. Magnetic measurements demonstrate the feasibility of these novel type of magnets and a new prototype is being design for its use on light sources under the I.Fast EU program.…”
Section: Magnetsmentioning
confidence: 99%
“…However, the CLIC prototype is more challenging, as it is a tuneable permanent magnet combining dipole and quadrupole components, with a very high field of 2.3 T at its centre. A recent prototype has been built by CIEMAT as part of the EuCard2 program [69]. Magnetic measurements demonstrate the feasibility of these novel type of magnets and a new prototype is being design for its use on light sources under the I.Fast EU program.…”
Section: Magnetsmentioning
confidence: 99%
“…Most of the design challenges of the DRs are driven by the extremely high bunch density and the associated collective effects. In this respect, the DR parameters (Table 7.7) are carefully chosen and optimised in order to mitigate these effects [95,96]. In the case of CLIC, the steady state emittance is dominated by Intra-Beam Scattering (IBS).…”
Section: Low Emittance Generationmentioning
confidence: 99%
“…In the case of CLIC, the steady state emittance is dominated by Intra-Beam Scattering (IBS). The ring energy [97] and lattice design [96], (racetrack shape with TME arc cells with variable field dipoles [98] and long straight sections filled with super-conducting wiggler [99] FODOs) is optimized for reducing IBS. The larger emittance specification of ILC, allows for higher ring energy, thus relaxing collective effects.…”
Section: Low Emittance Generationmentioning
confidence: 99%
“…Even at this large detuning factor, the TMEs are preferable for their compactness, in particular for a ring in which radiation damping is dominated by wigglers. The use of variable bends with gradient in the TME cell was also studied using a similar approach, further reducing the IBS growth rates [25].…”
Section: Mitigating Collective Effects In the Clic Drsmentioning
confidence: 99%
“…At the same time, as shown in Fig. 5 (right), by raising the field and using Nb3Sn wire technology, the reduction of the ring circumference can be also achieved, with beneficial impact to all type of collective effects, including to a potential impedance reduction [25,27]. These specifications were used for the superconducting wiggler prototype and short model developped for the CLIC DRs [26,27].…”
Section: Mitigating Collective Effects In the Clic Drsmentioning
confidence: 99%