Paper |
Title |
Page |
MOPAB095 |
Concept Design for the CLS2 Accelerator Complex |
354 |
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- M.J. Boland, P.J. Hunchak
University of Saskatchewan, Saskatoon, Canada
- C.K. Baribeau, D. Bertwistle, J.M. Patel, H. Shaker, X. Shen, M.J. Sigrist
CLS, Saskatoon, Saskatchewan, Canada
- F. Le Pimpec
EuXFEL, Schenefeld, Germany
- E.J. Wallén
LBNL, Berkeley, California, USA
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The Canadian Light Source has been in operation since 2005 and is now looking at a design concept to upgrade to a fourth generation storage ring. A brief overview is given of a possible accelerator complex layout, including some details on the lattice design and injection system. A full energy linac is being explored as an option for top-up injection and to future proof the facility for a potential FEL upgrade in the future.
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2021-MOPAB095
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About • |
paper received ※ 23 May 2021 paper accepted ※ 28 July 2021 issue date ※ 13 August 2021 |
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MOPAB310 |
Vertical Phase Space Measurement Progress at Canadian Light Source |
963 |
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- Y. Yousefi Sigari, D. Bertwistle, M.J. Boland
CLS, Saskatoon, Saskatchewan, Canada
- M.J. Boland
University of Saskatchewan, Saskatoon, Canada
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A key feature of third-generation light sources is their small vertical opening angle, which is difficult to measure experimentally. To reconstruct the vertical phase space, one can scan the beam’s position using X-ray synchrotron radiation (XSR) and a pinhole camera. The XSR diagnostic beamline, operational in the wavelength region of 0.05 - 0.15 nm, in Canadian Light Source (CLS) is qualified to measure the beam position with X-ray radiation. Using the corrector magnets in CLS lattice made of 12 identical double-bend achromats (DBA) cells, vertical iterations can be executed parallel to the beam’s original orbit. The outcomes of this experiment are: 1) the vertical beam positions that are monitored by BPMs, and 2) the X-ray image of the beam that is projected through the pinhole. The bumps were simulated using Matlab Middle Layer (MML) for Accelerator control systems to get an insight of the source point’s position in the XSR’s bending magnet. The simulation shows the position of the source point depends on which corrector sets are chosen.
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Poster MOPAB310 [0.328 MB]
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2021-MOPAB310
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About • |
paper received ※ 19 May 2021 paper accepted ※ 28 July 2021 issue date ※ 13 August 2021 |
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WEXC05 |
First Results Operating a Long-Period EPU in Universal Mode at the Canadian Light Source |
2566 |
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- W.A. Wurtz, C.K. Baribeau, D. Bertwistle, M.J. Sigrist
CLS, Saskatoon, Saskatchewan, Canada
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The Quantum Materials Spectroscopy Centre beamline at the Canadian Light Source (CLS) requires photons with energies as low as 15 eV with circular polarization at the end station. This energy range is accomplished on the 2.9 GeV CLS storage ring using an elliptically polarizing undulator (EPU) with a 180 mm period, which we call EPU180. In order to realize circular polarized photons at the end station with this low energy, we must overcome two technical issues. First, the beamline optics distort the polarization of the light, so we compensate by providing light with a flattened, tilted polarization ellipse at the source point - a mode of operation known as universal mode. Second, the device has a strong effect on the electron beam due to dynamic focusing and is capable of reducing the injection efficiency to zero. We overcome this non-linear dynamic focusing using current strips adhered to the vacuum chamber. In this report, we present the first results with operating EPU180 in universal mode and we recover the dynamic aperture using the current strips.
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2021-WEXC05
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About • |
paper received ※ 13 May 2021 paper accepted ※ 05 July 2021 issue date ※ 11 August 2021 |
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WEPAB121 |
Design and Simulation of Transparent Injection Upgrade for the CLS Storage Ring |
2885 |
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- P.J. Hunchak, M.J. Boland
University of Saskatchewan, Saskatoon, Canada
- D. Bertwistle, M.J. Boland
CLS, Saskatoon, Saskatchewan, Canada
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The Canadian Light Source (CLS) synchrotron uses four fast kicker magnets to inject electrons into the storage ring from a 2.9 GeV booster ring. The injection occurs over several turns of the stored beam, which is also perturbed by the injection kickers. The resultant oscillations of the stored beam can negatively affect beamline experiments, so it is desirable to implement an injection scheme which does not disturb the stored beam. Injection schemes of this type allow for transparent injection and are beneficial for planned top-up operations of the CLS storage ring. Many alternative injection techniques were examined as they apply to the CLS storage ring. Pulsed multipole magnets and a non-linear kicker (NLK) are the most viable options for integration with the current ring. Non-linear kicker designs are also being considered for the proposed CLS2 and studying the NLK in the limitations of the current machine provides insight to guide the work on the new machine. Simulation with the accelerator code ELEGANT shows the viability of the non-linear kicker design as developed at BESSY, MAX IV and SOLEIL for transparent injection at the CLS.
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2021-WEPAB121
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About • |
paper received ※ 19 May 2021 paper accepted ※ 16 July 2021 issue date ※ 01 September 2021 |
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THPAB223 |
Energy Compression System Radio Frequency Design at the Canadian Light Source |
4231 |
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- E.J. Ericson, D. Bertwistle, M.J. Boland
CLS, Saskatoon, Saskatchewan, Canada
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The Canadian Light Source (CLS), Canada’s only synchrotron light source, is considering a linear accelerator (LINAC) upgrade. As a result, the radio frequency (RF) structure in the downstream Energy Compression System (ECS) needs to be redesigned. In this paper, we describe the design process followed to determine the geometry of the RF structure cells and coupler.
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DOI • |
reference for this paper
※ https://doi.org/10.18429/JACoW-IPAC2021-THPAB223
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About • |
paper received ※ 18 May 2021 paper accepted ※ 28 July 2021 issue date ※ 28 August 2021 |
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